Download Kinetix 350 Single-axis EtherNet/IP Servo Drives User Manual
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User Manual Kinetix 350 Single-axis EtherNet/IP Servo Drives Catalog Numbers 2097-V31PR0-LM, 2097-V31PR2-LM, 2097-V32PR0-LM, 2097-V32PR2-LM, 2097-V32PR4-LM, 2097-V33PR1-LM, 2097-V33PR3-LM, 2097-V33PR5-LM, 2097-V33PR6-LM, 2097-V34PR3-LM, 2097-V34PR5-LM, 2097-V34PR6-LM Important User Information Solid-state equipment has operational characteristics differing from those of electromechanical equipment. Safety Guidelines for the Application, Installation and Maintenance of Solid State Controls (publication SGI-1.1 available from your local Rockwell Automation sales office or online at http://www.rockwellautomation.com/literature/) describes some important differences between solid-state equipment and hard-wired electromechanical devices. Because of this difference, and also because of the wide variety of uses for solid-state equipment, all persons responsible for applying this equipment must satisfy themselves that each intended application of this equipment is acceptable. In no event will Rockwell Automation, Inc. be responsible or liable for indirect or consequential damages resulting from the use or application of this equipment. The examples and diagrams in this manual are included solely for illustrative purposes. Because of the many variables and requirements associated with any particular installation, Rockwell Automation, Inc. cannot assume responsibility or liability for actual use based on the examples and diagrams. No patent liability is assumed by Rockwell Automation, Inc. with respect to use of information, circuits, equipment, or software described in this manual. Reproduction of the contents of this manual, in whole or in part, without written permission of Rockwell Automation, Inc., is prohibited. Throughout this manual, when necessary, we use notes to make you aware of safety considerations. WARNING: Identifies information about practices or circumstances that can cause an explosion in a hazardous environment, which may lead to personal injury or death, property damage, or economic loss. ATTENTION: Identifies information about practices or circumstances that can lead to personal injury or death, property damage, or economic loss. Attentions help you identify a hazard, avoid a hazard, and recognize the consequence. SHOCK HAZARD: Labels may be on or inside the equipment, for example, a drive or motor, to alert people that dangerous voltage may be present. BURN HAZARD: Labels may be on or inside the equipment, for example, a drive or motor, to alert people that surfaces may reach dangerous temperatures. IMPORTANT Identifies information that is critical for successful application and understanding of the product. Allen-Bradley, CompactLogix, ControlFLASH, ControlLogix, Kinetix, MP-Series, TL-Series, RSLogix, Rockwell Automation, Rockwell Software, Stratix 2000, and TechConnect are trademarks of Rockwell Automation, Inc.. Trademarks not belonging to Rockwell Automation are property of their respective companies. Table of Contents Preface About This Publication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Who Should Use This Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Conventions Used in This Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Additional Resources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 7 7 8 Chapter 1 Start Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 About the Kinetix 350 Drive System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Catalog Number Explanation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Agency Compliance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 CE Requirements. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Chapter 2 Install the Kinetix 350 Drive System Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . System Design Guidelines. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . System Mounting Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transformer Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Circuit Breaker/Fuse Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Enclosure Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Minimum Clearance Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . Electrical Noise Reduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Bonding Drives. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Bonding Multiple Subpanels. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Establishing Noise Zones. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cable Categories for Kinetix 350 Drive Components. . . . . . . . . . . . Noise Reduction Guidelines for Drive Accessories. . . . . . . . . . . . . . . Mount Your Kinetix 350 Drive. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 16 16 17 17 18 19 20 20 22 23 25 25 28 Chapter 3 Kinetix 350 Drive Connector Data Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Kinetix 350 Drive Connectors and Indicators . . . . . . . . . . . . . . . . . . . . . . Safe Torque-off Connector Pinout. . . . . . . . . . . . . . . . . . . . . . . . . . . . . I/O Connector Pinout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Motor Feedback (MF) Connector Pinout . . . . . . . . . . . . . . . . . . . . . . Ethernet Communication Connector Pinout . . . . . . . . . . . . . . . . . . . AC Input Power Connector Pinout . . . . . . . . . . . . . . . . . . . . . . . . . . . . Back-up Power Connector Pinout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Shunt Resistor and DC Bus Connector Pinout. . . . . . . . . . . . . . . . . . Motor Power Connector Pinout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Control Signal Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Digital Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Motor Brake Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Ethernet Communication Specifications . . . . . . . . . . . . . . . . . . . . . . . Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 29 30 31 32 33 33 34 34 34 34 35 35 38 39 3 Table of Contents 24V DC Back-up Power Specifications . . . . . . . . . . . . . . . . . . . . . . . . . 39 Motor Feedback Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 Feedback Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 Chapter 4 Connect the Kinetix 350 Drive System Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 Basic Wiring Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Recommended Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Route Power and Signal Wiring. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Determine the Input Power Configuration . . . . . . . . . . . . . . . . . . . . . . . . . Three-phase Power Wired to Three-phase Drives . . . . . . . . . . . . . . . Single-phase Power Wired to Single-phase Drives . . . . . . . . . . . . . . . Voltage Doubler Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Isolation Transformer in Grounded Power Configurations . . . . . . Three-phase Power Wired to Single-phase Drives . . . . . . . . . . . . . . . Voiding of CE Compliance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Grounding Your Kinetix 350 Drive System. . . . . . . . . . . . . . . . . . . . . . . . . Ground Your Drive to the System Subpanel . . . . . . . . . . . . . . . . . . . . Ground Multiple Subpanels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Wiring Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Wiring Guidelines. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Wiring the Kinetix 350 Drive Connectors. . . . . . . . . . . . . . . . . . . . . . . . . . Wire the Safe Torque-off (STO) Connector . . . . . . . . . . . . . . . . . . . . Wire the Back-up Power (BP) Connector . . . . . . . . . . . . . . . . . . . . . . Wire the Input Power (IPD) Connector. . . . . . . . . . . . . . . . . . . . . . . . Wire the Motor Power (MP) Connector . . . . . . . . . . . . . . . . . . . . . . . Apply the Motor Cable Shield Clamp. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Feedback and I/O Cable Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Flying-lead Feedback Cable Pin-outs . . . . . . . . . . . . . . . . . . . . . . . . . . . Wiring the Feedback and I/O Connectors . . . . . . . . . . . . . . . . . . . . . . . . . Wire the I/O Connector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Wire the Low-profile Connector Kit . . . . . . . . . . . . . . . . . . . . . . . . . . . Shunt Resistor Connections. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Ethernet Cable Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 48 48 48 49 50 50 51 51 53 54 54 55 55 58 59 59 59 60 61 66 67 68 69 69 70 71 72 Chapter 5 Configure and Start Up the Kinetix 350 Drive System 4 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Keypad Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Status Indicators. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configure the Kinetix 350 Drive Ethernet IP Address . . . . . . . . . . . . . . . Ethernet Connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Kinetix 350 Drive Ethernet Port Configuration . . . . . . . . . . . . . . . . . Obtain the Kinetix 350 Drives’ Current Ethernet Settings . . . . . . . Configure the IP Address Manually (static address). . . . . . . . . . . . . . Configure the IP Address Automatically (dynamic address) . . . . . . Configure the Logix EtherNet/IP Controller . . . . . . . . . . . . . . . . . . . . . . . Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 75 76 77 79 79 79 79 80 81 82 Table of Contents Configure the Logix Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configure the Kinetix 350 Drive. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configure the Motion Group. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configure Axis Properties . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Download the Program . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Apply Power to the Kinetix 350 Drive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Test and Tune the Axes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Test the Axes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Tune the Axes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Disable EnableInputChecking Using a RSLogix Message Instruction . 82 84 87 88 91 91 92 92 95 98 Chapter 6 Kinetix 350 Drive Safe Torque-off Feature Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99 Certification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 Important Safety Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 Safety Category 3 Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 Stop Category Definition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 Performance Level and Safety Integrity Level (SIL) CL2 . . . . . . . . 101 Description of Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 Functional Proof Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 Troubleshooting the Safe Torque-off Function . . . . . . . . . . . . . . . . 102 PFD and PFH Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 PFD and PFH Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 Safe Torque-off Connector Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 STO Connector Pinouts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 Wiring Your Safe Torque-off Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 European Union Directives . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 Safe Torque-off Wiring Requirements. . . . . . . . . . . . . . . . . . . . . . . . . 105 Kinetix 350 Drive Safe Torque-off Feature . . . . . . . . . . . . . . . . . . . . . . . . 106 Safe Torque-off Feature Bypass . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106 Kinetix 350 Drive Safe Torque-off Wiring Diagrams . . . . . . . . . . . . . . . 107 Safe Torque-off Signal Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108 Chapter 7 Troubleshoot the Kinetix 350 Drive Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Safety Precautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Interpret Status Indicators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Four-digit Display Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Fault Codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Status Indicators. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General System Behavior. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Logix Controller and Drive Behavior . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Kinetix 350 Drive Exception Behavior . . . . . . . . . . . . . . . . . . . . . . . . Web Server Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 109 109 110 110 111 117 119 121 121 125 5 Table of Contents Appendix A Specifications and Dimensions Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Kinetix 350 Drive Power Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . Circuit Breaker/Fuse Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Contactor Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transformer Specifications for Input Power . . . . . . . . . . . . . . . . . . . Power Dissipation Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Environmental Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Maximum Feedback Cable Lengths . . . . . . . . . . . . . . . . . . . . . . . . . . . Weight Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Certifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AC Line Filter Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Shunt Resistor Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Product Dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127 128 131 132 132 133 133 133 133 134 134 135 136 137 Appendix B Interconnect Diagrams Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Interconnect Diagram Notes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Wiring Examples . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Shunt Resistor Wiring Example. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Kinetix 350 Drive/Rotary Motor Wiring Examples . . . . . . . . . . . . . . . . Kinetix 350 Drive/Actuator Wiring Examples . . . . . . . . . . . . . . . . . . . . . Motor Brake Currents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . System Block Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 139 140 141 143 144 146 149 150 Appendix C Upgrade the Kinetix 350 Drive Firmware Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Upgrade Drive Firmware with ControlFLASH Software . . . . . . . . . . . Before You Begin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configure Logix Communication. . . . . . . . . . . . . . . . . . . . . . . . . . . . . Upgrade Firmware. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Verify the Firmware Upgrade . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 153 154 154 155 157 161 Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 163 6 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Preface About This Publication This manual provides detailed installation instructions for mounting, wiring, and troubleshooting your Kinetix® 350 drive; and system integration for your drive/ motor combination with a Logix controller. Who Should Use This Manual This manual is intended for engineers and technicians directly involved in the installation and wiring of the Kinetix 350 drive and programmers directly involved in operation, field maintenance, and integration of the Kinetix 350 drive. If you do not have a basic understanding of the Kinetix 350 drive, contact your local Rockwell Automation sales representative for information on available training courses. Conventions Used in This Manual The conventions starting below are used throughout this manual: • Bulleted lists such as this one provide information, not procedural steps. • Numbered lists provide sequential steps or hierarchical information. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 7 Preface These documents contain additional information concerning related products from Rockwell Automation. Additional Resources Resource Description Kinetix 350 Single-axis EtherNet/IP Servo Drive Installation Instructions, publication 2097-IN008 Information on installing your Kinetix 350 drive system. Kinetix 300 Shunt Resistor Installation Instructions, publication 2097-IN002 Information on installing and wiring the Kinetix 300 shunt resistors. Kinetix 300 AC Line Filter Installation Instructions, publication 2097-IN003 Information on installing and wiring the Kinetix 300 AC line filter. Kinetix 300 I/O Terminal Expansion Block Installation Instructions, publication 2097-IN005 Information on installing and wiring the Kinetix 300 I/O terminal expansion block. CompactLogix L3ER Controllers User Manual, publication 1769-UM021 Information on installing, configuring, programming, and operating a CompactLogix“ system. Stratix 2000 Ethernet Unmanaged Switches Installation Instructions, publication 1783-IN001 Information on installing and operating a Stratix 2000“ Ethernet Switches. Ethernet/IP Benefits of Industrial Connectivity in Industrial Apps White Paper, publication 1585WP001A Provides general guidelines and theory for Ethernet/IP industrial systems. Industrial Ethernet Media, publication 1585-BR001 This brochure provides connectivity solutions for Ethernet networks and integrated architecture. Guidance for Selecting Cables for EtherNet/IP Networks White Paper, publication ENET-WP007 This guide is arranged to help you select cabling based on the application, environmental conditions, and mechanical requirements Integrated Motion on SERCOS and EtherNet/IP Systems - Analysis and Comparison White Paper, publication MOTION-WP007 This white paper compares and contrasts SERCOS and EtherNet/IP with a ControlLogix Controller. Industrial Automation Wiring and Grounding Guidelines, publication 1770-4.1 Provides general guidelines for installing a Rockwell Automation industrial system. System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001 Information, examples, and techniques designed to minimize system failures caused by electrical noise. EMC Noise Management DVD, publication GMC-SP004 Kinetix Motion Control Selection Guide, publication GMC-SG001 Specifications, motor/servo-drive system combinations, and accessories for Kinetix motion control products. Motion Analyzer software, download at http://www.ab.com/e-tools Drive and motor sizing with application analysis software. ControlLogix Controllers User Manual, publication 1756-UM001 Information on installing, configuring, programming, and operating a ControlLogix system. CIP Motion Configuration and Startup User Manual, publication MOTION-UM003 Information on configuring and troubleshooting your ControlLogix and CompactLogix EtherNet/IP network modules. ControlFLASH Firmware Upgrade Kit User Manual, publication 1756-QS105 For ControlFLASH information not specific to any drive family. Rockwell Automation Configuration and Selection Tools, website http://www.ab.com/e-tools Online product selection and system configuration tools, including AutoCAD (DXF) drawings. Rockwell Automation Product Certification, website http://www.rockwellautomation.com/products/certification For declarations of conformity (DoC) currently available from Rockwell Automation. National Electrical Code, published by the National Fire Protection Association of Boston, MA An article on wire sizes and types for grounding electrical equipment. Rockwell Automation Industrial Automation Glossary, publication AG-7.1 A glossary of industrial automation terms and abbreviations. You can view or download publications at http://www.rockwellatuomation.com/literature. To order paper copies of technical documentation, contact your local Allen-Bradley distributor or Rockwell Automation sales representative. 8 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Chapter 1 Start Introduction Use this chapter to become familiar with the Kinetix 350 drive components. This chapter also reviews design and installation requirements for Kinetix 350 drive systems. Topic Page Introduction 9 About the Kinetix 350 Drive System 10 Catalog Number Explanation 12 Agency Compliance 13 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 9 Chapter 1 Start The Kinetix 350 single-axis EtherNet/IP servo drive is designed to provide a solution for applications with output power requirements between 0.4…3.0 kW (2…12 A rms). About the Kinetix 350 Drive System Table 1 - Kinetix 350 Drive System Overview Kinetix 350 System Component Cat. No. Description Kinetix 350 Single-axis EtherNet/IP Servo Drive 2097-V3xPRx-LM Kinetix 350 Single-axis EtherNet/IP drives with safe torque-off feature are available with 120/240V or 480V AC input power. AC Line Filters 2090 2097-Fx Bulletin 2090 and Bulletin 2097-Fx AC line filters are required to meet CE with Kinetix 350 drives without an integrated line filter. Bulletin 2097 filters are available in foot mount and side mount. Shunt Module 2097-Rx Bulletin 2097 shunt resistors connect to the drive and provide shunting capability in regenerative applications. Terminal block for I/O connector 2097-TB1 50-pin terminal block. Use with IOD connector for control interface connections. Stratix 2000 Ethernet Switch 1783-US05T An Ethernet switch divides an Ethernet network into segments and directs network traffic efficiently. Logix Controller Platform 1769-L18ERM-BB1B 1769-L27ERM-QBFC1B 1769-L33ERM 1769-L36ERM 1769-L30ERM 1756-L6x 1756-L7x CompactLogix controller with integrated dual-port Ethernet/IP interface serves as communication link with the Kinetix 350 drive system. The communication link uses EtherNet/IP protocol over a copper cable. RSLogix 5000 Software 9324-RLD300ENE RSLogix 5000 software (version 20.xx or later) provides support for programming, commissioning, and maintaining the Logix family of controllers. Rotary Servo Motors MP-Series, TL-Series Compatible rotary motors include the MP-Series (Bulletin MPL, MPM, MPF, and MPS) and TL-Series (Bulletin TLY) motors. Linear Stages MP-Series (Ballscrew) Compatible stages include MP-Series (Bulletin MPAS) Integrated Linear Stages. Electric Cylinders MP-Series, TL-Series Compatible electric cylinders include MP-Series and TL- Series (Bulletin MPAR, TLAR, and MPAI) Electric Cylinders. Cables Motor/brake and feedback cables Motor power/brake and feedback cables include SpeedTec and threaded DIN connectors at the motor. Power/brake cables have flying leads on the drive end and straight connectors that connect to servo motors. Feedback cables have flying leads that wire to low-profile connector kits on the drive end and straight connectors on the motor end. Communication cables 1585J-M8CBJM-x (shielded) or 1585J-M8UBJM-x (high-flex shielded) Ethernet cable. 10 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Start Chapter 1 Figure 1 - Typical Kinetix 350 Drive Installation CompactLogix Controller Platform 1769-L33ERM Shown 1783-US05T Stratix 2000 Switch 1 Three-phase Input Power Line Disconnect Device RSLogix 5000 Software P W R 2 3 Input Fusing 4 5 1585J-M8CBJM-x (shielded) or 11585J-M8UBJM-x (high-flex shielded) Ethernet Cable Other Ethernet/IP Compatible Drives 2097-V3xxxx-LM Kinetix 350 Drive 2097-TB1 Terminal Expansion Block 2097-Fx AC Line Filter (optional equipment) 2097-F1 Filter Shown 24V DC Control Back-up Power Supply (optional equipment) MP-Series Integrated Linear Stages (MPAS-B9xxx ballscrew shown) 2090-K2CK-D15M Low-profile Connector Kit Bulletin 2090 Motor Feedback Cables MP-Series and TL-Series Rotary Motors (MPL-Bxxxx motors shown) 2097-Rx Shunt Resistor (optional equipment) Bulletin 2090 Motor Power Cables MP-Series and TL-Series Electric Cylinders (MPAR-Bxxxx electric cylinders shown) MP-Series Heavy Duty Electric Cylinders (MPAI-Bxxxx electric cylinders shown) Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 11 Chapter 1 Start Catalog Number Explanation Kinetix 350 drive catalog numbers and descriptions are listed in these tables. ) Table 2 - Kinetix 350 Drives (single-phase) Cat. No. Description 2097-V31PR0-LM Kinetix 350,120/240V, 1 Ø, 2.0 A 2097-V31PR2-LM Kinetix 350, 120/240V, 1 Ø, 4.0 A 2097-V32PR0-LM Kinetix 350, 240V, 1 Ø, 2.0 A, with integrated filter 2097-V32PR2-LM Kinetix 350, 240V, 1 Ø, 4.0 A, with integrated filter 2097-V32PR4-LM Kinetix 350, 240V, 1 Ø, 8.0 A, with integrated filter Table 3 - Kinetix 350 Drives (single/three-phase Cat. No. Description 2097-V33PR1-LM Kinetix 350, 120V 1 Ø, 240V 3 Ø, 2.0 A 2097-V33PR3-LM Kinetix 350, 120V 1 Ø, 240V 3 Ø, 4.0 A 2097-V33PR5-LM Kinetix 350, 120V 1 Ø, 240V 3 Ø, 8.0 A 2097-V33PR6-LM Kinetix 350, 120V 1 Ø, 240V 3 Ø, 12.0 A Table 4 - Kinetix 350 Drives (three-phase) Cat. No. Description 2097-V34PR3-LM Kinetix 350, 480V, 3 Ø, 2.0 A 2097-V34PR5-LM Kinetix 350, 480V, 3 Ø, 4.0 A 2097-V34PR6-LM Kinetix 350, 480V, 3 Ø, 6.0 A Kinetix 350 Drive Accessories 12 Cat. No. Drive Components 2097-Fx AC line filters 2097-TB1 Terminal block for I/O connector 2097-Rx Shunt resistors Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Start Agency Compliance Chapter 1 If this product is installed within the European Union and has the CE mark, the following regulations apply. ATTENTION: Meeting CE requires a grounded system. The method of grounding the AC line filter and drive must match. Failure to do this renders the filter ineffective and may cause damage to the filter. For grounding examples, refer to Grounding Your Kinetix 350 Drive System on page 54. For more information on electrical noise reduction, refer to the System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001. CE Requirements To meet CE requirements, these requirements apply: • Install an AC line filter (Bulletin 2090 or 2097) as close to the drive as possible. • Use 2090 series motor power cables or use connector kits and terminate the cable shields to the subpanel with clamp provided. • Use 2090 series motor feedback cables or use connector kits and properly terminate the feedback cable shield. Drive-to-motor power and feedback cables must not exceed 20 m (65.6 ft). • Install the Kinetix 350 system inside an enclosure. Run input power wiring in conduit (grounded to the enclosure) outside of the enclosure. Separate signal and power cables. • Segregate input power wiring and motor power cables from control wiring and motor feedback cables. Use shielded cable for power wiring and provide a grounded 360° clamp termination. Refer to Appendix B on page 141 for interconnect diagrams, including input power wiring and drive/motor interconnect diagrams. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 13 Chapter 1 Start Notes: 14 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Chapter 2 Install the Kinetix 350 Drive System Introduction This chapter describes system installation guidelines used in preparation for mounting your Kinetix 350 drive components. Topic Page Introduction 15 System Design Guidelines 16 Electrical Noise Reduction 20 Mount Your Kinetix 350 Drive 28 ATTENTION: Plan the installation of your system so that you can perform all cutting, drilling, tapping, and welding with the system removed from the enclosure. Because the system is of the open type construction, be careful to keep any metal debris from falling into it. Metal debris or other foreign matter can become lodged in the circuitry, which can result in damage to components. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 15 Chapter 2 Install the Kinetix 350 Drive System System Design Guidelines Use the information in this section when designing your enclosure and planning to mount your system components on the panel. For on-line product selection and system configuration tools, including AutoCAD (DXF) drawings of the product, refer to http://www.ab.com/e-tools. System Mounting Requirements • To comply with UL and CE requirements, the Kinetix 350 system must be enclosed in a grounded conductive enclosure offering protection as defined in standard EN 60529 (IEC 529) to IP4X such that they are not accessible to an operator or unskilled person. A NEMA 4X enclosure exceeds these requirements providing protection to IP66. • The panel you install inside the enclosure for mounting your system components must be on a flat, rigid, vertical surface that won’t be subjected to shock, vibration, moisture, oil mist, dust, or corrosive vapors. • Size the drive enclosure so as not to exceed the maximum ambient temperature rating. Consider heat dissipation specifications for all drive components. • Segregate input power wiring and motor power cables from control wiring and motor feedback cables. Use shielded cable for power wiring and provide a grounded 360° clamp termination. • Use high-frequency (HF) bonding techniques to connect the enclosure, machine frame, and motor housing, and to provide a low-impedance return path for high-frequency (HF) energy and reduce electrical noise. • Use 2090 series motor feedback cables or use connector kits and properly terminate the feedback cable shield. Drive-to-motor power and feedback cables must not exceed 20 m (65.6 ft). IMPORTANT System performance was tested at these cable length specifications. These limitations are also a CE requirement. Refer to the System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001, to better understand the concept of electrical noise reduction. 16 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Install the Kinetix 350 Drive System Chapter 2 Transformer Selection The Kinetix 350 drive does not require an isolation transformer for three-phase input power. However, a transformer may be required to match the voltage requirements of the controller to the available service. To size a transformer for the main AC power inputs, refer to Circuit Breaker/ Fuse Specifications on page 131 and Transformer Specifications for Input Power on page 132. IMPORTANT If using an autotransformer, make sure that the phase to neutral/ground voltages do not exceed the input voltage ratings of the drive. IMPORTANT Use a form factor of 1.5 for single and three-phase power (where form factor is used to compensate for transformer, drive, and motor losses, and to account for utilization in the intermittent operating area of the torque speed curve). For example, sizing a transformer to the voltage requirements of catalog number 2097-V34PR6-LM = 3 kW continuous x 1.5 = 4.5 KVA transformer. Circuit Breaker/Fuse Selection The Kinetix 350 drives use internal solid-state motor short-circuit protection and, when protected by suitable branch circuit protection, are rated for use on a circuit capable of delivering up to 100,000 A. Fuses or circuit breakers that are adequate and can withstand interrupt ratings, as defined in NEC or applicable local codes, are permitted. The Bulletin 140M and 140U products are another acceptable means of protection. As with fuses and circuit breakers, you must make sure that the selected components are properly coordinated and meet applicable codes including any requirements for branch circuit protection. When applying the 140M/140U product, evaluation of the short circuit available current is critical and must be kept below the short circuit current rating of the 140M/140U product. In most cases, class CC, J, L, and R fuses selected to match the drive input current rating will meet the NEC requirements or applicable local codes, and provide the full drive capabilities. Use dual element, time delay (slow-acting) fuses to avoid nuisance trips during the inrush current of power initialization. Refer to Kinetix 350 Drive Power Specifications on page 128 for input current and inrush current specifications for your Kinetix 350 drive. Refer to Circuit Breaker/Fuse Specifications on page 131 for recommended circuit breakers and fuses. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 17 Chapter 2 Install the Kinetix 350 Drive System Enclosure Selection This example is provided to assist you in sizing an enclosure for your Bulletin 2097 drive system. You need heat dissipation data from all components planned for your enclosure to calculate the enclosure size. With no active method of heat dissipation (such as fans or air conditioning) either of the following approximate equations can be used. Metric Standard English A= 0.38Q 1.8T - 1.1 A= 4.08Q T - 1.1 Where T is temperature difference between inside air and outside ambient (°C), Q is heat generated in enclosure (Watts), and A is enclosure surface area (m2). The exterior surface of all six sides of an enclosure is calculated as Where T is temperature difference between inside air and outside ambient (°F), Q is heat generated in enclosure (Watts), and A is enclosure surface area (ft2). The exterior surface of all six sides of an enclosure is calculated as A = 2dw + 2dh + 2wh A = (2dw + 2dh + 2wh) /144 Where d (depth), w (width), and h (height) are in meters. Where d (depth), w (width), and h (height) are in inches. If the maximum ambient rating of the Kinetix 350 drive system is 40 °C (104 °F) and if the maximum environmental temperature is 20 °C (68 °F), then T=20. In this example, the total heat dissipation is 416 W (sum of all components in enclosure). So, in the equation below, T=20 and Q=416. A= 0.38 (416) = 4.53 m 1.8 (20) - 1.1 2 In this example, the enclosure must have an exterior surface of at least 4.53 m2. If any portion of the enclosure is not able to transfer heat, do not include heat in the calculation. Because the minimum cabinet depth to house the Kinetix 350 system (selected for this example) is 332 mm (13 in.), the cabinet needs to be approximately 2000 x 700 x 332 mm (78.7 x 27.6 x 13.0 in.) HxWxD. 2 x (0.332 x 0.70) + 2 x (0.332 x 2.0) + 2 x (0.70 x 2.0) = 4.59 m2 Because this cabinet size is considerably larger than what is necessary to house the system components, it may be more efficient to provide a means of cooling in a smaller cabinet. Contact your cabinet manufacturer for options available to cool your cabinet. 18 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Install the Kinetix 350 Drive System Chapter 2 Minimum Clearance Requirements This section provides information to assist you in sizing your cabinet and positioning your Kinetix 350 system components. IMPORTANT Mount the module in an upright position as shown. Do not mount the drive module on its side. Figure 2 illustrates minimum clearance requirements for proper airflow and installation: • Additional clearance is required depending on the accessory items installed. • An additional 9.7 mm (0.38 in.) clearance is required left of the drive if the I/O expansion terminal block is used. • An additional 26 mm (1.0 in.) clearance is required right of the drive when the heatsink is present. • An additional 36 mm (1.42 in.) is required right of the drive when the side-mount line filter is present. An additional 50 mm (2.0 in.) is required behind the drive when the rear-mount line filter is present. • An additional 5.0 mm (0.19 in.) clearance is required in front of the drive when the 2090-K2CK-D15M feedback connector kit is used. • Additional clearance is required for the cables and wires connected to the top, front, and bottom of the drive. • An additional 150 mm (6.0 in.) is required when the drive is mounted adjacent to noise sensitive equipment or clean wireways. Refer to page 137 for Kinetix 350 drive dimensions. Figure 2 - Minimum Clearance Requirements 25.0 mm (1.0 in.) Clearance for Airflow and Installation A 3 mm (0.12 in.) Side Clearance 3 mm (0.12 in.) Side Clearance 25.0 mm (1.0 in.) Clearance for Airflow and Installation Drive Cat. No. A 2097-V31PR0-LM 185 (7.29) 2097-V31PR2-LM 185 (7.29) 2097-V32PR0-LM 230 (9.04) 2097-V32PR2-LM 230 (9.04) 2097-V32PR4-LM 230 (9.04) 2097-V33PR1-LM 185 (7.29) 2097-V33PR3-LM 185 (7.29) 2097-V33PR5-LM 185 (7.29) 2097-V33PR6-LM 230 (9.04) 2097-V34PR3-LM 185 (7.29) 2097-V34PR5-LM 185 (7.29) 2097-V34PR6-LM 230 (9.04) Refer to page 133 for power dissipation specifications. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 19 Chapter 2 Install the Kinetix 350 Drive System Electrical Noise Reduction This section outlines best practices that minimize the possibility of noise-related failures as they apply specifically to Kinetix 350 system installations. For more information on the concept of high-frequency (HF) bonding, the ground plane principle, and electrical noise reduction, refer to the System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001. Bonding Drives Bonding is the practice of connecting metal chassis, assemblies, frames, shields, and enclosures to reduce the effects of electromagnetic interference (EMI). Unless specified, most paints are not conductive and act as insulators. To achieve a good bond between drive and the subpanel, surfaces need to be paint-free or plated. Bonding metal surfaces creates a low-impedance return path for highfrequency energy. IMPORTANT To improve the bond between the drive and subpanel, construct your subpanel out of zinc plated (paint-free) steel. Improper bonding of metal surfaces blocks the direct return path and allows high-frequency energy to travel elsewhere in the cabinet. Excessive highfrequency energy can effect the operation of other microprocessor controlled equipment. 20 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Install the Kinetix 350 Drive System Chapter 2 These illustrations show recommended bonding practices for painted panels, enclosures, and mounting brackets. Figure 3 - Recommended Bonding Practices for Painted Panels Stud-mounting the Subpanel to the Enclosure Back Wall Stud-mounting a Ground Bus or Chassis to the Subpanel Subpanel Back Wall of Enclosure Mounting Bracket or Ground Bus Welded Stud Subpanel Star Washer Nut Flat Washer Welded Stud Scrape Paint Nut Flat Washer Use a wire brush to remove paint from threads to maximize ground connection. Use plated panels or scrape paint on front of panel. If the mounting bracket is coated with a non-conductive material (anodized or painted), scrape the material around the mounting hole. Star Washer Bolt-mounting a Ground Bus or Chassis to the Back-panel Subpanel Bolt Tapped Hole Ground Bus or Mounting Bracket Nut Star Washer Scrape paint on both sides of panel and use star washers. Star Washer Flat Washer Nut Flat Washer Star Washer If the mounting bracket is coated with a non-conductive material (anodized or painted), scrape the material around the mounting hole. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 21 Chapter 2 Install the Kinetix 350 Drive System Bonding Multiple Subpanels Bonding multiple subpanels creates a common low impedance exit path for the high frequency energy inside the cabinet. Subpanels that are not bonded together may not share a common low impedance path. This difference in impedance may affect networks and other devices that span multiple panels: • Bond the top and bottom of each subpanel to the cabinet by using 25.4 mm (1.0 in.) by 6.35 mm (0.25 in.) wire braid. As a rule, the wider and shorter the braid is, the better the bond. • Scrape the paint from around each fastener to maximize metal-to-metal contact. Figure 4 - Multiple Subpanels and Cabinet Recommendations Wire Braid 25.4 mm (1.0 in.) by 6.35 mm (0.25 in.) Ground bus bonded to the subpanel. Remove paint from cabinet. 22 Wire Braid 25.4 mm (1.0 in.) by 6.35 mm (0.25 in.) Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Install the Kinetix 350 Drive System Chapter 2 Establishing Noise Zones Observe these guidelines when individual input power components are used in the Kinetix 350 system: • The clean zone (C) exits left of the Kinetix 350 system and includes the I/ O wiring, feedback cable, Ethernet cable, and DC filter (gray wireway). • The dirty zone (D) exits right of the Kinetix 350 system (black wireway) and includes the circuit breakers, transformer, 24V DC power supply, contactors, AC line filter, motor power, and safety cables. • The very dirty zone (VD) is limited to where the AC line (EMC) filter VAC output jumpers over to the drive. Shielded cable is required only if the very dirty cables enter a wireway. Figure 5 - Noise Zones (Bulletin 2090 AC line filters) Dirty Wireway Clean Wireway D Very Dirty Zone Segregated (not in wireway) VD Bulletin 2090 AC Line Filter (optional) D Contactors VD 24V Motor Brake PS Circuit Breaker Kinetix 350 Drive (4) Ethernet (shielded) Cable No sensitive equipment within 150 mm (6.0 in.).(2) C DC Filter XFMR (3) (1), Ethernet, and I/O Feedback Cables C D I/O (1), Motor Power, and Safety Cables Route encoder/analog/registration shielded cables. Route 24V DC I/O Shielded Cable (1) If drive system I/O cable contains (dirty) relay wires, route cable in dirty wireway. (2) For tight spaces use a grounded steel shield. For examples, refer to the System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001. (3) This is a clean 24V DC available for any device that may require it. The 24V enters the clean wireway and exits to the left. (4) This is a dirty 24V DC available for motor brakes and contactors. The 24V enters the dirty wireway and exits to the right. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 23 Chapter 2 Install the Kinetix 350 Drive System Figure 6 - Noise Zones (Bulletin 2097 AC line filters) Dirty Wireway Clean Wireway D D Contactors Very Dirty Zone Segregated (not in wireway) VD 24V Motor Brake PS VD Kinetix 350 Drive Circuit Breaker Kinetix 350 Ethernet (shielded) Cable Bulletin 2097 AC line filters mount to side, as shown, or behind DC Filter No sensitive equipment within 150 C (4) XFMR (3) I/O (1), Ethernet, and Feedback Cables C D I/O (1), Motor Power, and Safety Cables Route encoder/analog/registration shielded cables. Route 24V DC I/O Shielded Cable (1) If drive system I/O cable contains (dirty) relay wires, route cable in dirty wireway. (2) For tight spaces use a grounded steel shield. For examples, refer to the System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001. (3) This is a clean 24V DC available for any device that may require it. The 24V enters the clean wireway and exits to the left. (4) This is a dirty 24V DC available for motor brakes and contactors. The 24V enters the dirty wireway and exits to the right. 24 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Install the Kinetix 350 Drive System Chapter 2 Cable Categories for Kinetix 350 Drive Components These table indicate the zoning requirements of cables connecting to the Kinetix 350 drive components. Table 5 - Kinetix 350 Drive Components Zone Wire/Cable Connector Very Dirty L1, L2, L3 (unshielded cable) IPD X U, V, W (motor power) MP X B+-, B-, BR (shunt resistor) BC X 24V DC BP Control COM, 24V DC control, safety enable, and feedback signals for safe-off feature STO Motor feedback MF Registration IOD Others Ethernet Port 1 Dirty Method Clean Ferrite Sleeve Shielded Cable X X X X X X X X X X Noise Reduction Guidelines for Drive Accessories Refer to this section when mounting an AC line filter or shunt resistor module for guidelines designed to reduce system failures caused by excessive electrical noise. AC Line Filters If you are using a Bulletin 2090 line filter, mount the filter on the same panel as the Kinetix 350 drive, and as close to the drive as possible. Observe these guidelines when mounting your AC line filter: • Good HF bonding to the panel is critical. For painted panels, refer to the examples on page 21. • Segregate input and output wiring as far as possible. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 25 Chapter 2 Install the Kinetix 350 Drive System Shunt Resistors Observe these guidelines when mounting your shunt resistor outside the enclosure: • Mount shunt resistor and wiring in the very dirty zone or in an external shielded enclosure. • Mount resistors in a shielded and ventilated enclosure outside the cabinet. • Keep unshielded wiring as short as possible. Keep shunt wiring as flat to the cabinet as possible. Figure 7 - Shunt Resistor Outside the Enclosure Shunt Wiring Methods: Twisted pair in conduit (first choice). Shielded twisted pair (second choice). Twisted pair, two twists per foot (min) (third choice). Clean Wireway 150 mm (6.0 in.) clearance (min) on all four sides of the shunt module. Customer-supplied Metal Enclosure Metal Conduit (where required by local code) Dirty Wireway Enclosure D D Contactor No sensitive equipment within 150 Kinetix 350 Drive Ethernet (shielded) Cable VD VD 24V Motor Brake PS Very dirty connections Circuit Breaker AC Line Filter DC Filter XFMR I/O (1), Ethernet, and C Feedback Cables C D Route Encoder/Analog/Registration Shielded Cables I/O (1), Motor Power and Safety Cables Route 24V DC I/O Shielded Cable (1) If drive system I/O cable contains (dirty) relay wires, route cable in dirty wire way. (2) When space does not permit 150 mm (6.0 in.) clearance, install a grounded steel shield between the drive and clean wireway. For examples, refer to the System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001. 26 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Install the Kinetix 350 Drive System Chapter 2 When mounting your shunt module inside the enclosure, follow these additional guidelines: • Mount the shunt resistor anywhere in the dirty zone, but as close to the Kinetix 350 drive as possible. • Shunt wires can be run with motor power cables. • Keep unshielded wiring as short as possible. Keep shunt wiring as flat to the cabinet as possible. • Separate shunt wires from other sensitive, low-voltage signal cables. Figure 8 - Shunt Resistor inside the Enclosure Clean Wireway Dirty Wireway Shunt Wiring Methods: Twisted pair in conduit (first choice). Shielded twisted pair (second choice). Twisted pair, two twists per foot (min) (third choice). Enclosure D D Contactor Very dirty zone VD VD 24V Motor Brake PS Circuit Breaker Kinetix 350 Drive Ethernet (shielded) Cable AC Line Filter DC Filter XFMR No sensitive equipment within 150 I/O (1), Ethernet, and Feedback Cables C C D D Route Encoder/Analog/Registration Shielded Cables I/O (1), Motor Power, and Safety Cables Route 24V DC I/O Shielded Cable (1) If drive system I/O cable contains (dirty) relay wires, route cable in dirty wire way. (2) When space does not permit 150 mm (6.0 in.) clearance, install a grounded steel shield between the drive and clean wireway. For examples, refer to the System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001. Motor Brake The brake is mounted inside the motor and how you connect to the drive depends on the motor series. Refer to Kinetix 350 Drive/Rotary Motor Wiring Examples beginning on page 146 for the interconnect diagram of your drive/motor combination. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 27 Chapter 2 Install the Kinetix 350 Drive System Mount Your Kinetix 350 Drive This procedure assumes you have prepared your panel and understand how to bond your system. For installation instructions regarding other equipment and accessories, refer to the instructions that came with those products. ATTENTION: This drive contains electrostatic discharge (ESD) sensitive parts and assemblies. You are required to follow static control precautions when you install, test, service, or repair this assembly. If you do not follow ESD control procedures, components can be damaged. If you are not familiar with static control procedures, refer to Guarding Against Electrostatic Damage, publication 8000-4.5.2, or any other applicable ESD Protection Handbook. Follow these steps to mount your Kinetix 350 drive. 1. Lay out the position for the Kinetix 350 drive and accessories in the enclosure. Refer to Establishing Noise Zones on page 23 for panel layout recommendations. Mounting hole dimensions for the Kinetix 350 drive are shown in Appendix A on page 127. 2. Attach the Kinetix 350 drive to the cabinet, first by using the upper mounting slots of the drive and then the lower. The recommended mounting hardware is M4 (#6-32) steel machine screws torqued to 1.1 N•m (9.8 lb•in). Observe bonding techniques as described in Bonding Drives on page 20. IMPORTANT To improve the bond between the Kinetix 350 drive and subpanel, construct your subpanel out of zinc plated (paint-free) steel. 3. Tighten all mounting fasteners. 28 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Chapter 3 Kinetix 350 Drive Connector Data Introduction This chapter provides power, feedback, and I/O connector locations and signal descriptions for your Kinetix 350 drive. Topic Page Introduction 29 Kinetix 350 Drive Connectors and Indicators 30 Control Signal Specifications 35 Motor Feedback Specifications 40 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 29 Chapter 3 Kinetix 350 Drive Connector Data Although the physical size of the Kinetix 350 drives vary, the location of the connectors and indicators is identical. Kinetix 350 Drive Connectors and Indicators Figure 9 - Kinetix 350 Drive Connector and Indicators 10 2 3 4 5 6 13 14 350 7 12 8 15 1 11 9 10 Kinetix 350 Drive, Top View (2097-V33PR5-LM drive is shown) Kinetix 350 Drive, Front View (2097-V33PR5-LM drive is shown) Kinetix 350 Drive, Bottom View (2097-V33PR5-LM drive is shown) Item Description Item Description 1 Mains (IPD) connector 9 Motor feedback (MF) connector 2 Data status indicator and diagnostic display 10 Ground lug 3 Memory module socket 11 Shunt resistor and DC bus (BC) connector 4 Network status indicator 12 Back-up power (BP) connector 5 Module status indicator 13 Display control push buttons (3) 6 Axis status indicator 14 Motor power (MP) connector 7 Ethernet communication port (Port 1) 15 Safe torque-off (STO) connector 8 I/O (IOD) connector Table 6 - Kinetix 350 Drive Connectors 30 Designator Description Connector IPD AC input power 3-position or 4-position plug/header PORT1 Ethernet communication port RJ45 Ethernet IOD I/O SCSI 50 pin high density connector MF Motor feedback 15-pin high-density D-shell (male) BP Back-up power 2-pin quick-connect terminal block BC Shunt Resistor and DC Bus 5-pin quick-connect terminal block MP Motor power 6-pin quick-connect terminal block STO Safe torque off (STO) Terminal 6-pin quick-connect terminal block Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Connector Data Chapter 3 Safe Torque-off Connector Pinout The Kinetix 350 drive ships with the (6-pin) wiring-plug header that connects your safety circuit to the Kinetix 350 drive safe torque-off (STO) connector. If your system does not use the safe torque-off feature, follow instructions in Safe Torque-off Feature Bypass starting on page 106 to wire the drive with motionallowed jumpers. Figure 10 - Safe Torque-off Connector Bottom view of the Kinetix 350 drive. (2097-V33PR5-LM drive is shown) Safe Torque-off (STO) Connector 1 2 5 6 3 4 ol contr V DC M 4 2 + rol CO Cont tus y sta Safet ty input 1 Safe ty COM 2 Safe ty input Safe Wiring Plug Header Table 7 - Kinetix 350 Drive Safe Torque-off Connector Pinout STO Pin Description Signal 1 +24V DC output from the drive +24V DC control 2 +24V DC output common Control COM 3 Safety status Safety Status 4 Safety input 1 (+24V DC to enable) Safety Input 1 5 Safety common Safety COM 6 Safety input 2 (+24V DC to enable) Safety Input 2 IMPORTANT Pins STO-1 (+24V DC Control) and STO-2 (Control COM) are used only by the motion-allowed jumpers to enable the drive when the safe torque-off function is not be used. When the safe torque-off function is in operation, the 24V supply must come from an external source. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 31 Chapter 3 Kinetix 350 Drive Connector Data I/O Connector Pinout IOD Pin Description Signal 1…25 Reserved Reserved 26 +/- Overtravel, enable, and home common COM 27 Negative hardware overtravel NEG_OT 28 Positive hardware overtravel POS_OT 29 Drive enable ENABLE 30 Home switch HOME_SW 31…35 Reserved — 36 Registration common REG_COM 37…38 Reserved — 39 Registration input REG 40…42 Reserved — 43 Motor brake release positive MTR_BRAKE+ 44 Motor brake release negative MTR_BRAKE- 44…50 Reserved — Figure 11 - Pin Orientation for 50-pin SCSI I/O (IOD) Connector 32 26 1 50 25 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Connector Data Chapter 3 Motor Feedback (MF) Connector Pinout MF Pin Description Signal MF Pin Description Signal 1 Sine differential input+ AM+ differential input+ SIN+ AM+ 9 Reserved — 2 Sine differential inputAM- differential input- SINAM- 10 Data differential input Index pulse- DATAIM- 3 Cosine differential input+ BM+ differential input+ COS+ BM+ 11 Motor thermal switch (normally closed) (1) TS 4 Cosine differential inputBM- differential input- COSBM- 12 Single-ended 5V Hall effect commutation S1 5 Data differential input + Index pulse+ DATA+ IM+ 13 Single-ended 5V Hall effect commutation S2 6 Common ECOM 14 Encoder power (+5V) EPWR_5V (2) 7 Encoder power (+9V) EPWR_9V (2) 15 Reserved — 8 Single-ended 5V Hall effect commutation S3 (1) Not applicable unless motor has integrated thermal protection. (2) Encoder power supply uses either 5V or 9V DC based on encoder/motor used. IMPORTANT Drive-to-motor power and feedback cable length must not exceed 20 m (65.6 ft). System performance was tested at these specifications and also apply when meeting CE requirements. Figure 12 - Pin Orientation for 15-pin Motor Feedback (MF) Connector Pin 10 Pin 5 Pin 15 Pin 11 Pin 6 Pin 1 Ethernet Communication Connector Pinout Port 1 Pin Description Signal Port 1 Pin Description Signal 1 Transmit port (+) data terminal + TX 5 — — 2 Transmit port (-) data terminal - TX 6 Receive port (-) data terminal - RX 3 Receive port (+) data terminal + RX 7 — — 4 — — 8 — — Figure 13 - Pin Orientation for 8-pin Ethernet Communication (port 1) Port 1 8 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 33 Chapter 3 Kinetix 350 Drive Connector Data AC Input Power Connector Pinout IPD Designator Description (2097-V31PRx-LM drives) Signal IPD Designator Description (2097-V32PRx-LM drives) Signal L2/N AC power in (non-doubler operation) L2/N L2 AC power in L2 L1 AC power in L1 L1 AC power in L1 N AC power neutral (120V doubler only) N PE Protective earth (ground) PE PE Protective earth (ground) PE IPD Designator Description (2097-V33PRx-LM, and 2097V34PRx-LM drives) Signal L3 AC power in (three-phase models) L3 L2 AC power in L2 L1 AC power in L1 PE Protective earth (ground) PE Back-up Power Connector Pinout BP Designator Description Signal +24V Positive 24V DC +24V DC -24V 24V DC power supply return Return Shunt Resistor and DC Bus Connector Pinout BC Designator B+ B+ BR BB- Description Positive DC bus/Shunt resistor Shunt resistor Negative DC bus Signal B+ B+ BR BB- Motor Power Connector Pinout 34 MP Designator Description Signal PE Protective earth (ground) PE W Motor power out W V Motor power out V U Motor power out U Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Connector Data Control Signal Specifications Chapter 3 This section provides a description of the Kinetix 350 drive I/O (IOD), communication, shunt resistor and DC bus (BC), and back-up power (BP) connectors. Digital Inputs Five fixed inputs are available for the machine interface on the Kinetic 350 drive. IMPORTANT To improve registration input EMC performance, refer to the System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001. IMPORTANT Over-travel limit input devices must be normally closed. The five digital inputs (IOD-27…IOD-30 and IOD-39) have fixed pin assignments. Table 8 - Understanding Digital Inputs IOD Pin Signal Description Capture Time Edge/Level Sensitive IOD-29 ENABLE Optically isolated, single-ended active high signal. Current loading is nominally 9 mA. A 24V DC input is applied to this terminal to enable the axis. 0.5 ms Level IOD-30 HOME Optically isolated, single-ended active high signal. Current loading is nominally 9 mA. Home switch (normally open contact) inputs axis require 24V DC (nominal). 0.5 ms Edge IOD-39 REG Fast registration inputs are required to inform the motor interface to capture the positional information with less than 5 μs uncertainty. Optically isolated, single-ended active high signal. Current loading is nominally 9 mA. A 24V DC input is applied to this terminal to enable axis. 5 μs Edge IOD-27 IOD-28 NEG_OT POS_OT Overtravel detection is available as an optically isolated, single-ended active high signal. Current loading is nominally 9 mA per input. The positive/negative limit switch (normally closed contact) inputs for axis require 24V DC (nominal). 1 ms Level Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 35 Chapter 3 Kinetix 350 Drive Connector Data Table 9 - Understanding Digital Input Functions Function Enable Description Behavior If the controller configuration specifies checking of the enable input, an active state enables the power electronics to control the motor and an inactive state prevents motion. The drive generates an exception if the input is inactive when the controller commands motion and has authorized checking. The drive behavior in this situation is programmable. By default drive enable input checking is enabled. If the checking is authorized and the input is disabled the drive will issue a Drive Enable Start Inhibit and you will not be able to issue a Servo On instruction from the controller. To disable the Enable function: • Tie input to 24V DC • Write a RSlogix message instruction that changes enableInputChecking or Attribute 736 to zero, see instructions on page 98 Home An active state indicates to a homing sequence that the referencing sensor has been seen. Typically, a transition of this signal is used to establish a reference position for the machine axis. Registration An inactive-to-active transition (also known as a positive transition) or active-to-inactive transition (also known as a negative transition) is used to latch position values for use in registration moves. Positive Over-travel If the controller configuration specifies checking of the hardware overtravel inputs, an inactive state indicates that a position limit has been exceeded in the positive direction. The drive generates an exception if the input is inactive when the controller authorizes checking. The drive behavior in this situation is programmable. Negative Over-travel If the controller configuration specifies checking of the hardware overtravel inputs, an inactive state indicates that a position limit has been exceeded in the negative direction. The drive generates an exception if the input is inactive when the controller authorizes checking. The drive behavior in this situation is programmable. The function is always inactive unless armed by the controller. The function is always active. To disable function: • Tie input to 24V • Set to Fault Status Only Table 10 - Digital Input Specifications Attribute Value Type Active high, single-ended, current sinking Functions Enable, Home, Positive Over-travel, Negative Over-travel, Registration Input current (with 24V applied) 9 mA, max On-state input voltage 4.2…24V @ 2…9 mA total Off-state input voltage 0…2.5V Pulse reject filtering (Registration functions only) 120 ns, nom Pulse reject filtering, default (all other input functions, can be configured) 1.0 ms, nom Propagation delay (Registration function only) 5 μs Registration repeatability 200 ns Input reaction time (Disable) 2 ms, max Input reaction time (Enable, Positive Over-travel inputs) 2 ms, max The digital inputs are optically isolated and sinks up to 24V DC. Electrical details are shown in Table 9 on page 36. You can set up the inputs for PNP sourcing or NPN sinking. 36 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Connector Data Chapter 3 Figure 14 - Sourcing of Digital Inputs 1.2 k +24V ENABLE, HOME_SW, POS_OT, or NEG_OT 1.2 k ENABLE, HOME_SW, POS_OT, or NEG_OT GND COM Figure 15 - Sinking of Digital Inputs 1.2 k GND ENABLE, HOME_SW, POS_OT, or NEG_OT 1.2 k ENABLE, HOME_SW, POS_OT, or NEG_OT COM +24V Figure 16 - Sourcing of Registration Digital Input 1.2 k +24V REG 1.2 k REG GND REG_COM Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 37 Chapter 3 Kinetix 350 Drive Connector Data Figure 17 - Sinking of Registration Digital Input 1.2 k GND REG 1.2 k REG REG_COM +24V Motor Brake Output The two digital outputs (IOD-43 and IOD-44) have fixed pin assignments for motor brake function. The following schematic show how to wire your motor brake. Kinetix 350 Drive 24V DC MTR_BRAKE MTR_BRAKE + 44 43 CR1 Motor Brake Black 7 BR+ White 9 BR- 24V DC COM Use these guideline to wire your brake: • Connect a diode, 1N4004 or equivalent, as shown on both the rely and the motor brake coils. • Wire the output as sourcing. • The motor brake output is active on enable. • Set the motor engage and disengage times based on the motor selected. 38 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Connector Data Chapter 3 Ethernet Communication Specifications An RJ45 100 Mbit Ethernet connector (port 1) is provided on the Kinetix 350 drive. It is fully compliant to the EtherNet/IP standard. Restrict the location of all Ethernet cabling to clean zones with minimal electromagnetic interference. Attribute Value Communication 100BASE-TX, full duplex Auto MDI/MDIX crossover detection/correction Yes Cabling Rockwell Automation CAT5E shielded, 100 m (328 ft), max 24V DC Back-up Power Specifications The Kinetix 350 drive can use an external power supply to power the logic and communication circuits. If an independent 24V (@ 1 A) power supply is connected to the BP connector, the logic and communication circuits remain active during a mains input power loss. Attribute Value Input voltage 20…26V DC Current 500 mA Inrush, max 30 A Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 39 Chapter 3 Kinetix 350 Drive Connector Data Motor Feedback Specifications The drive accepts motor feedback signals from the following types of encoders with these general specifications. Table 11 - Motor Feedback General Specifications Attribute Value Feedback device support • Stegmann Hiperface • Generic TTL Incremental • Tamagawa 17-bit Serial Power supply (EPWR5V) 5.13…5.67V, 400 mA, max Power supply (EPWR9V) 8.3…9.9V, 275 mA, max Thermostat Single-ended, under 500 = no fault, over 10 k= fault The Kinetix 350 drives support multiple types of feedback devices by using the 15-pin (MF) motor feedback connector and sharing connector pins in many cases. Table 12 - Motor Feedback Signals by Device Type 40 MF Pin Stegmann Hiperface Generic TTL Incremental Tamagawa 17-bit Serial 1 SIN+ AM+ — 2 SIN- AM- — 3 COS+ BM+ — 4 COS- BM- — 5 DATA+ IM+ DATA+ 6 ECOM ECOM ECOM 7 EPWR9V — — 8 — S3 — 9 — — — 10 DATA- IM- DATA- 11 TS TS TS 12 — S1 — 13 — S2 — 14 EPWR5V EPWR5V EPWR5V 15 — — — Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Connector Data Chapter 3 This is the motor thermostat interface schematic. Although the thermostat signal is shown for all feedback types, some motors may not support this feature because it is not part of the feedback device. Figure 18 - Motor Thermostat Interface +5V +5V 6.81 kΩ 1 kΩ TS 0.01 μF Kinetix 350 Drive Table 13 - Motor Thermostat State Specifications State Resistance at TS (1) No Fault 500 Fault 10 k (1) Resistance is measured between TS (MF pin 11) and ECOM (MF pin 6) Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 41 Chapter 3 Kinetix 350 Drive Connector Data Table 14 - Stegmann Hiperface Specifications Attribute Value Protocol Hiperface Memory support Not programmed, or programmed with Allen-Bradley motor data Hiperface data communication RS485, 9600 bps, 8 data bits, no parity Sine/Cosine interpolation 2048 counts/sine period Input frequency (AM/BM) 250 kHz, max Input voltage (AM/BM) 0.6...1.2V, p-p, measured at the drive inputs Line loss detection (AM/BM) Average (sin2 + cos2) > constant Figure 19 - Stegmann Hiperface Interface, SIN and COS Signals 47 pF Kinetix 350 Drive 26.7 kΩ 1 kΩ 10 kΩ + to A/D Converter 1 kΩ 56 pF 56 pF 10 kΩ +5V 1 kΩ SIN+ or COS+ 1 kΩ + - 1 kΩ 1 kΩ SIN- or COS- to AqB Counter 56 pF 56 pF 1 kΩ Figure 20 - Stegmann Hiperface Interface, DATA Signals +5V 10 kΩ 1 kΩ + - DATA+ 1 kΩ DATA- to AqB Counter 56 pF 10 Ω 56 pF Shaded area indicates components that are part of the circuit, but support other feedback device types (not used for Stegmann Hiperface support). to UART Kinetix 350 Drive from UART from UART 42 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Connector Data Chapter 3 Table 15 - Generic TTL Incremental Specifications Attribute Value TTL incremental encoder support 5V, differential A quad B Quadrature interpolation 4 counts/square wave period Differential input voltage (AM, BM, and IM) 1.0…7.0V DC current draw (AM, BM, and IM) 30 mA, max Input signal frequency (AM, BM, and IM) 5.0 MHz, max Edge separation (AM and BM) 42 ns min, between any two edges Line loss detection (AM and BM) Average (AM2 + BM2) > constant Hall inputs (S1, S2, and S3) Single-ended, TTL, open collector, or none Figure 21 - Generic TTL Incremental, AM and BM Signals 47 pF Kinetix 350 Drive 26.7 kΩ 1 kΩ 10 kΩ + to A/D Converter 10 kΩ 1 kΩ 56 pF 56 pF Shaded area indicates components that are part of the circuit, but support other feedback device types (not used for Generic TTL incremental support). 1 kΩ AM+ or BM+ + - 1 kΩ AM- or BM- to AqB Counter 1 kΩ 56 pF 56 pF Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 43 Chapter 3 Kinetix 350 Drive Connector Data Figure 22 - Generic TTL Interface, IM Signals +5V 10 kΩ 1 kΩ MTR_IM+ + - 1 kΩ MTR_IM- to AqB Counte 56 pF 56 pF 10 kΩ Shaded area indicates components that are part of the circuit, but support other feedback device types (not used for Generic TTL incremental support). to UART from UART from UART Kinetix 350 Drive Figure 23 - Generic TTL Interface, S1, S2, or S3 Signals +5V +5V 1 kΩ S1, S2, or S3 1 kΩ 56 pF Kinetix 350 Drive Table 16 - Tamagawa 17-bit Serial Specifications Attribute Value Tamagawa model support TS5669N124 Protocol Tamagawa proprietary Memory support Programmed with Allen-Bradley motor data Differential input voltage 1.0…7.0V Data communication 2.5 Mbps, 8 data bits, no parity Battery 3.6V, located external to drive in low-profile connector kit Refer to Figure 20 for the Tamagawa 17-bit serial interface schematic. It is identical to the Stegmann Hiperface (DATA) signals schematic. 44 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Connector Data Chapter 3 Feedback Power Supply The Kinetix 350 drive generates +5V and +9V DC for motor feedback power. Short circuit protection and separate common mode filtering for each channel is included. Table 17 - Motor Feedback Power Specifications Supply Reference +5V DC +9V DC Voltage Current mA Min Nominal Max Min Max EPWR_5V 5.13 5.4 5.67 0 400 (1) (2) EPWR_9V 8.3 9.1 9.9 0 275 (2) (3) (1) 400 mA on the 5V supply with no load on the 9V supply. (2) 300 mA on the 5V supply with 150 mA on the 9V supply. (3) 275 mA on the 9V supply with no load on the 5V supply. Figure 24 - Pin Orientation for 15-pin Motor Feedback (MF) Connector Pin 15 Pin 11 Pin 6 Pin 10 Pin 5 Pin 1 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 45 Chapter 3 Kinetix 350 Drive Connector Data Notes: 46 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Chapter 4 Connect the Kinetix 350 Drive System Introduction Basic Wiring Requirements This chapter provides procedures for wiring your Kinetix 350 system components and making cable connections. Topic Page Introduction 47 Basic Wiring Requirements 47 Grounding Your Kinetix 350 Drive System 54 Power Wiring Requirements 55 Wiring Guidelines 58 Wiring the Kinetix 350 Drive Connectors 59 Apply the Motor Cable Shield Clamp 66 Feedback and I/O Cable Connections 67 Wiring the Feedback and I/O Connectors 69 Kinetix 350 Drive (IOD connector and terminal block) 69 Shunt Resistor Connections 71 Ethernet Cable Connections 72 This section contains basic wiring information for the Kinetix 350 drive. ATTENTION: Plan the installation of your system so that you can perform all cutting, drilling, tapping, and welding with the system removed from the enclosure. Because the system is of the open type construction, be careful to keep any metal debris from falling into it. Metal debris or other foreign matter can become lodged in the circuitry, which can result in damage to components. SHOCK HAZARD: To avoid hazard of electrical shock, perform all mounting and wiring of the Bulletin 2097 drive prior to applying power. Once power is applied, connector terminals may have voltage present even when not in use. IMPORTANT This section contains common PWM servo system wiring configurations, size, and practices that can be used in a majority of applications. National Electrical Code, local electrical codes, special operating temperatures, duty cycles, or system configurations take precedence over the values and methods provided. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 47 Chapter 4 Connect the Kinetix 350 Drive System Recommended Cables The Motor Power Cable Compatibility table on page 62 and Motor Feedback Cables for Specific Motor/Feedback Combinations table on page 67 show the cables Rockwell Automation recommends you use with the Kinetix 350 drive. IMPORTANT Factory-made cables are designed to minimize EMI and are recommended over hand-built cables to optimize system performance. If it is necessary for you to build or modify your own cable, follow these guidelines: • Connect the cable shield to the connector shells on both ends of the cable with a complete 360° connection. • Use twisted pair cable whenever possible. Twist differential signals with each other and twist single-ended signals with the appropriate ground return. Refer to the Kinetix Motion Control Selection Guide, publication GMC-SG001, for low-profile connector kit, drive-end (mating) connector kit, and motor-end connector kit catalog numbers. Route Power and Signal Wiring Be aware that when you route power and signal wiring on a machine or system, radiated noise from nearby relays, transformers, and other electronic drives can be induced into motor or encoder feedback signals, input/output communication, or other sensitive low voltage signals. This can cause system faults and communication anomalies. Refer to Electrical Noise Reduction on page 20 for examples of routing high and low voltage cables in wireways. Refer to the System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001, for more information. Determine the Input Power Configuration This section contains examples of typical single-phase and three-phase facility input power wired to single-phase and three-phase Kinetix 350 drives. The grounded power configuration lets you ground your single-phase or threephase power at a neutral point. Match your secondary to one of the examples and be certain to include the grounded neutral connection. 48 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 Three-phase Power Wired to Three-phase Drives These examples illustrate grounded three-phase power wired to three-phase Kinetix 350 drives when phase-to-phase voltage is within drive specifications. Figure 25 - Three-phase (400/480V) Power Configuration (WYE secondary) 2097-V34PRx-LM Transformer (WYE) Secondary L3 Feeder and branch short circuit protection is not illustrated. L3 L2 L2 L1 AC Line Filter L1 M1 Contactor Input Fusing L3 IPD L3 L2 L2 L1 L1 Kinetix 350 Drives Three-phase AC Input E Bonded Cabinet Ground Bus Ground Grid or Power Distribution Ground IMPORTANT For the 480V Kinetix 350 drives to meet proper voltage creepage and clearance requirements, each phase voltage to ground must be less than or equal to 300V AC rms. This means that the power system must use center grounded wye secondary configuration for 400/480V AC mains. Figure 26 - Three-phase (240V) Power Configuration (Delta secondary) Transformer (Delta) Secondary 2097-V33PRx-LM L3 IPD L3 L3 L3 AC Line (1) L2 L2 Filter Feeder and branch short circuit protection is not illustrated. L2 L1 M1 Contactor Kinetix 350 Drives Three-phase AC Input L1 L1 L1 Input Fusing L2 E Bonded Cabinet Ground Bus Ground Grid or Power Distribution Ground (1) Leakage current from the line filter, in this configuration, typically is higher than a balanced (center ground) configuration. Figure 27 - Three-phase (240V) Power Configuration (Delta secondary) 2097-V33PRx-LM Transformer (Delta) Secondary L3 L3 Feeder and branch short circuit protection is not illustrated. L2 L2 L1 Input Fusing L1 AC Line (1) Filter M1 Contactor L3 IPD L3 L2 L2 Three-phase AC Input L1 L1 Kinetix 350 Drives E Bonded Cabinet Ground Bus Ground Grid or Power Distribution Ground (1) Leakage current from the line filter, in this configuration, typically is higher than a balanced (center ground) configuration. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 49 Chapter 4 Connect the Kinetix 350 Drive System Single-phase Power Wired to Single-phase Drives These examples illustrate grounded single-phase power wired to single-phase Kinetix 350 drives when phase-to-phase voltage is within drive specifications. IMPORTANT The 2097-V32PRx-LM models have integrated AC line filters and do not require the AC line filter shown in this diagram. Figure 28 - Single-phase Grounded Power Configurations Transformer Secondary 2097-V31PRx-LM L1 L1 240V AC Output AC Line Filter L2 L2 L2 Input Fusing L1 M1 Contactor 2097-V32PRx-LM IPD L1 IPD L1 L2/N L2 Kinetix 350 Drives Single-phase AC Input E Bonded Cabinet Ground Bus Ground Grid or Power Distribution Ground 2097-V31PRx -LM(1) Transformer Secondary 120V AC Output L1 AC Line Filter L2/N L2 (Neutral) L1 IPD L1 N L2 IPD L1 Input Fusing M1 Contactor L1 L2/N 2097-V33PRx -LM Kinetix 350 Drives Single-phase AC Input E Bonded Cabinet Ground Bus Ground Grid or Power Distribution Ground (1) This configuration applies to voltage-doubler operation for 2097-V31PRx-LM drives. Reducing transformer output reduces motor speed. Feeder and branch short circuit protection is not illustrated. Voltage Doubler Operation You can wire the 2097-V31PRx-LM drives with 120V input voltage and achieve twice the output voltage. To use the voltage-doubler circuit, connect the 120V single-phase input power to the IPD-L1 and IPD-N terminals. For Kinetix 350 drive power specifications, refer to Kinetix 350 Drive Power Specifications on page 128. For Kinetix 350 drive input wiring diagrams, refer to Power Wiring Examples on page 141. 50 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 Isolation Transformer in Grounded Power Configurations When using an isolation transformer, attach a chassis ground wire to the neutral connection. This grounded neutral connection does the following: • Prevents the system from floating and thereby avoids any high voltages that might otherwise occur, for example due to static electricity • Provides a solid earth path for fault conditions ATTENTION: If the supply transformer is an auto transformer (not recommended), do not add a chassis earth ground. A chassis earth ground should already be included elsewhere in the system and adding another would create a short. Three-phase Power Wired to Single-phase Drives This example illustrates grounded three-phase power wired to single-phase Kinetix 350 drives when phase-to-phase voltage is within drive specifications. Figure 29 - Single-phase Amplifiers on Three-phase Power (WYE) 2097-V32PRx-LM Transformer (WYE) Secondary L1 L1 L2 Input Fusing IPD L1 L2 Kinetix 350 Drives (System A) Single-phase AC Input IPD L1 L2 Kinetix 350 Drives (System B) Single-phase AC Input M1 (1) L2 L2 L3 L3 Input Fusing M2 (1) IPD L1 L2 L3 Grounded Neutral L1 Input Fusing Kinetix 350 Drives (System C) Single-phase AC Input M3 (1) Bonded Cabinet Ground Bus Ground Grid or Power Distribution Ground (1) Contactors (MI, M2, and M3) may be optional. For more information, refer to Understanding the Machinery Directive, publication SHB-900. AC line filter is optional, but is required for CE compliance. Feeder short circuit protection is not illustrated. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 51 Chapter 4 Connect the Kinetix 350 Drive System This example illustrates grounded three-phase power wired to single-phase Kinetix 350 drives when phase-to-phase voltage exceeds drive specifications. A neutral must be connected when single-phase drives are attached to a threephase isolating transformer secondary. It is not necessary that all three-phases be loaded with drives, but each drive must have its power return via the neutral connection. ATTENTION: Failure to connect the neutral can result in supply voltage swings at the individual drives. This occurs when the neutral point moves vectorially as a result of load variations normally experienced by the individual drives. The supply voltage swing may cause undervoltage and overvoltage trips on the drives, and the drive can be damaged if the overvoltage limit is exceeded. Figure 30 - Single-phase Amplifiers (one AC line filter per drive) Transformer (WYE) Secondary 2097-V31PRx-LM L1 L1 L1 AC Line Filter L2 L2 E L1 AC Line Filter L2 E L1 M1 Contactor L1 AC Line Filter L2 E N L2 IPD L1 IPD L1 N L2 IPD L1 N IPD L1 Kinetix 350 Drives (System A) Single-phase AC Input Kinetix 350 Drives (System A) Single-phase AC Input L2 Grounded Neutral Input Fusing IPD L1 L2 L3 L1 2097-V33PRx-LM IPD L1 L2 Kinetix 350 Drives (System A) Single-phase AC Input L2 Grounded Neutral Bonded Cabinet Ground Bus Ground Grid or Power Distribution Ground Feeder and branch short circuit protection is not illustrated. IMPORTANT 52 Providing an AC line filter for each drive is the preferred configuration and required for CE compliance. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 Voiding of CE Compliance The three-phase and neutral in-line filter applications described above may not be adequate from an EMC aspect for CE compliance. Therefore, EMC validity and CE marking by Rockwell Automation is voided when three-phase and neutral in line filters are used. ATTENTION: The three-phase isolation transformer and neutral in-line filter applications described in this document have not been tested for EMC by Rockwell Automation and products used in such installations are not considered CE marked by Rockwell Automation. If this three-phase isolation transformer and neutral in-line filter application is used, the responsibility for EMC validation lies with the user and CE marking of the system becomes the user's responsibility. If CE compliance is a customer requirement, single-phase line filters that have been tested by Rockwell Automation and specified for the product should be used. Refer to AC Line Filter Specifications on page 135 for catalog numbers. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 53 Chapter 4 Connect the Kinetix 350 Drive System Grounding Your Kinetix 350 Drive System All equipment and components of a machine or process system should have a common earth ground point connected to their chassis. A grounded system provides a safety ground path for short circuit protection. Grounding your modules and panels minimize shock hazard to personnel and damage to equipment caused by short circuits, transient overvoltages, and accidental connection of energized conductors to the equipment chassis. For CE grounding requirements, refer to CE Requirements in Chapter 1. IMPORTANT To improve the bond between the Kinetix 350 drive and subpanel, construct your subpanel out of zinc plated (paint-free) steel. Ground Your Drive to the System Subpanel ATTENTION: The National Electrical Code contains grounding requirements, conventions, and definitions. Follow all applicable local codes and regulations to safely ground your system. Refer to the illustration below for details on grounding your Kinetix 350 drive. Refer to Appendix B for the power wiring diagram for your Kinetix 350 drive. If the Kinetix 350 drive is mounted on a painted subpanel, ground the drive to a bonded cabinet ground bus by using a braided ground strap or 4.0 mm2 (12 AWG) solid copper wire 100 mm (3.9 in.) long. Figure 31 - Connecting the Braided Ground Strap Example Braided Ground Strap Ground Stud Bonded Cabinet Ground Bus Ground Grid or Power Distribution Ground For drive dimensions, refer to Product Dimensions on page 137. 54 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 Figure 32 - Chassis Ground Configuration (multiple Kinetix 350 drives on one panel) Chassis Ground Chassis Ground Chassis Ground Chassis Ground Bonded Ground Bar (optional) Bonded Cabinet Ground Bus Ground Grid or Power Distribution Ground Always follow NEC and applicable local codes. Ground Multiple Subpanels To ground multiple subpanels, refer to the figure below. HF bonding is not illustrated. For information, refer to Bonding Multiple Subpanels on page 22. Figure 33 - Subpanels Connected to a Single Ground Point Bonded Ground Bus Ground Grid or Power Distribution Ground Always follow NEC and applicable local codes. Power Wiring Requirements Wire should be copper with 75 °C (167 °F) minimum rating. Phasing of main AC power is arbitrary and an earth ground connection is required for safe and proper operation. Refer to Power Wiring Examples on page 143 for interconnect diagrams. IMPORTANT The National Electrical Code and local electrical codes take precedence over the values and methods provided. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 55 Chapter 4 Connect the Kinetix 350 Drive System Table 18 - Kinetix 350 Drive Power Wiring Requirements Terminals Cat. No. 2097-V31PR0-LM 2097-V32PR0-LM 2097-V32PR2-LM 2097-V33PR1-LM 2097-V33PR3-LM 2097-V34PR3-LM 2097-V34PR5-LM 2097-V34PR6-LM Description Pins Signals L3 L2 L1 PE (1) Mains input power (IPD connector) L2/N L1 N PE (2) L2 L1 PE (3) Recommended Wire Size mm2 (AWG) Strip Length mm (in.) Torque Value N•m (lb•in) Motor power cable depends on motor/drive combination. 7 (0.28) 0.5 (4.5) 2.5 (14) 2097-V32PR4-LM 2097-V33PR5-LM 4.0 (12) 7 (0.28) 0.5 (4.5) 2097-V31PR2-LM 2097-V33PR6-LM 6.0 (10) 7 (0.28) 0.56…0.79 (5.0…7.0) 2.5 (14) 7 (0.28) 0.5 (4.5) 4.0 (12) 7 (0.28) 0.5 (4.5) 2.5 (14) 7 (0.28) 0.5 (4.5) 4.0 (12) 7 (0.28) 0.5 (4.5) 1.5 (16) 6 (0.25) 0.5 (4.5) 2097-V31PR0-LM 2097-V31PR2-LM 2097-V32PR0-LM 2097-V32PR2-LM 2097-V32PR4-LM 2097-V33PR1-LM 2097-V33PR3-LM 2097-V33PR5-LM 2097-V34PR3-LM 2097-V34PR5-LM 2097-V34PR6-LM PE W V U Motor power (MP connector) 2097-V33PR6-LM 2097-V31PR0-LM 2097-V31PR2-LM 2097-V32PR0-LM 2097-V32PR2-LM 2097-V32PR4-LM 2097-V33PR1-LM 2097-V33PR3-LM 2097-V33PR5-LM 2097-V34PR3-LM 2097-V34PR5-LM 2097-V34PR6-LM B+ B+ BR BB- Brake /DC Bus (4) (BC connector) 2097-V33PR6-LM 2097-V3xPRx-LM 2097-V3xPRx-LM (1) (2) (3) (4) (5) 56 Control back-up power (BP connector) Safe torque-off (STO connector) +24V DC -24V DC STO-1 (5) STO-2 (5) STO-3 STO-4 STO-5 STO-6 +24V DC Control Control COM Safety Status Safety Input 1 Safety COM Safety Input 2 Applies to 2097-V33PRx-LM, and 2097-V34PRx-LM drive modules. Applies to 2097-V31PRx-LM drive modules. Applies to 2097-V32PRx-LM drive modules. Use for shunt resistor connection only. Use for bypassing the STO circuit only. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 ATTENTION: To avoid personal injury and/or equipment damage, make sure installation complies with specifications regarding wire types, conductor sizes, branch circuit protection, and disconnect devices. The National Electrical Code (NEC) and local codes outline provisions for safely installing electrical equipment. To avoid personal injury and/or equipment damage, make sure motor power connectors are used for connection purposes only. Do not use them to turn the unit on and off. To avoid personal injury and/or equipment damage, make sure shielded power cables are grounded to prevent potentially high voltages on the shield. Table 19 - Shunt Resistor Power Wiring Requirements Accessory Description 2097-Rx Shunt Resistor Connects to Terminals B+ BR Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Recommended Wire Size mm2 (AWG) Torque Value N•m (lb•in) 2.5 (14) 0.5 (4.5) 57 Chapter 4 Connect the Kinetix 350 Drive System Wiring Guidelines Use these guidelines as a reference when wiring the connectors on your Kinetix 350 drive power modules. IMPORTANT For connector locations of the Kinetix 350 drives, refer to Kinetix 350 Drive Connectors and Indicators on page 30. When tightening screws to secure the wires, refer to the tables beginning on page 55 for torque values. When removing insulation from wires, refer to the tables beginning on page 55 for strip lengths. IMPORTANT To improve system performance, run wires and cables in the wireways as established in Establishing Noise Zones on page 23. Follow these steps when wiring the connectors on your Kinetix 350 drive modules. 1. Prepare the wires for attachment to each connector plug by removing insulation equal to the recommended strip length. IMPORTANT Use caution not to nick, cut, or otherwise damage strands as you remove the insulation. 2. Route the cable/wires to your Kinetix 350 drive. 3. Insert wires into connector plugs. Refer to connector pinout tables in Chapter 3 or the interconnect diagrams in Appendix B. 4. Tighten the connector screws. 5. Gently pull on each wire to make sure it does not come out of its terminal; reinsert and tighten any loose wires. 6. Insert the connector plug into the module connector. 58 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Wiring the Kinetix 350 Drive Connectors Chapter 4 This section provides examples and wiring tables to assist you in making connections to the Kinetix 350 drive. Wire the Safe Torque-off (STO) Connector For the safe torque-off (STO) connector pinouts, feature descriptions, and wiring information, refer to Chapter 6 on page 99. Wire the Back-up Power (BP) Connector Kinetix 350 Drive, Front View + 24 - +24V DC -24V DC Table 20 - Back-up Power (BP) Connector Drive Cat. No. 2097-V3xPRx-LM Terminals +24V DC -24V DC Recommended Wire Size mm2 (AWG) Strip Length mm (in.) Torque Value N•m (lb•in) 1.5 (16) 6 (0.25) 0.5 (4.5) Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 59 Chapter 4 Connect the Kinetix 350 Drive System Wire the Input Power (IPD) Connector Kinetix 350 Drive Top View L3 L2/N L2 L2/N L2 L3 L1 L1 L2 L1 PE L2 L1 L1 N N L1 PE PE Table 21 - Input Power (IPD) Connector Recommended Wire Size mm2 (AWG) Strip Length mm (in.) Torque Value N•m (lb•in) 2.5 (14) 7 (0.28) 0.5 (4.5) 2097-V32PR4-LM 2097-V33PR5-LM 4.0 (12) 7 (0.28) 0.5 (4.5) 2097-V31PR2-LM 2097-V33PR6-LM 6.0 (10) 7 (0.28) 0.56…0.79 (5.0…7.0) Drive Cat. No. 2097-V31PR0-LM 2097-V32PR0-LM 2097-V32PR2-LM 2097-V33PR1-LM 2097-V33PR3-LM 2097-V34PR3-LM 2097-V34PR5-LM 2097-V34PR6-LM Terminals L3 L2 L1 PE (1) L2/N L1 N PE (2) L2 L1 PE (3) (1) Applies to 2097-V33PRx-LM, and 2097-V34PRx-LM drive modules. (2) Applies to 2097-V31PRx-LM drive modules. (3) Applies to 2097-V32PRx-LM drive modules. 60 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 Wire the Motor Power (MP) Connector Connections to the motor power (MP) connector include rotary motors and rotary motor driven actuators. Kinetix 350 Drive Bottom View PE W W V V U U Table 22 - Motor Power (MP) Termination Specifications Drive Cat. No. 2097-V31PR0-LM 2097-V31PR2-LM 2097-V32PR0-LM 2097-V32PR2-LM 2097-V32PR4-LM 2097-V33PR1-LM 2097-V33PR3-LM 2097-V33PR5-LM 2097-V34PR3-LM 2097-V34PR5-LM 2097-V34PR6-LM Terminals PE W V U 2097-V33PR6-LM Recommended Wire Size mm2 (AWG) 2.5 (14) Strip Length mm (in.) Torque Value N•m (lb•in) 7 (0.28) 0.5 (4.5) 4.0 (12) Cable Shield Terminations Factory-supplied motor power cables for MP-Series™ and TL-Series™ motors and actuator are shielded. The braided cable shield must terminate near the drive during installation. Remove small portion of the cable jacket to expose the shield braid and clamp the exposed shield to the panel. ATTENTION: To avoid hazard of electrical shock, ensure shielded power cables are grounded at a minimum of one point for safety. IMPORTANT For TL-Series motors, also connect the 152 mm (6.0 in.) termination wire to the closest earth ground. Refer to Pigtail Terminations on page 62 for more information. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 61 Chapter 4 Connect the Kinetix 350 Drive System Pigtail Terminations TL-Series motors have a short pigtail cable that connects to the motor, but is not shielded. The preferred method for grounding the TL-Series power cable on the motor side is to expose a section of the cable shield and clamp it directly to the machine frame. The motor power cable also has a 150 mm (6.0 in.) shield termination wire with a ring lug that connects to the closest earth ground. Use this method in addition to the cable clamp. The termination wire may be extended to the full length of the motor pigtail if necessary, but it is best to connect the supplied wire directly to ground without lengthening. Figure 34 - Pigtail Terminations Cable Braid Clamped (1) Connectors Motor Power Cable Pigtail Cable TL-Series Motor 150 mm (6.0) Termination Machine Frame (1) (1) (1) Remove paint from machine frame to be sure of proper HF-bond between machine frame, motor case, shield clamp, and ground stud. Table 23 - Motor Power Cable Compatibility Motor/Actuator Connector Motor/Actuator Cat. No. Motor Power Cables (with brake wires) Motor Power Cables (without brake wires) MPL-A/B15xxx-4xAA and MPL-A/B2xxx-4xAA 2090-XXNPMF-xxSxx (standard) 2090-CPBM4DF-xxAFxx (continuous-flex) 2090-CPWM4DF-xxAFxx (continuous-flex) MPL-A/B3xxx-7xAA, MPL-A/B4xxx-7xAA, and MPL-A/B45xxx-7xAA 2090-CPBM7DF-xxAAxx (1) (standard) 2090-CPBM7DF-xxAFxx (1) (continuous-flex) 2090-CPWM7DF-xxAAxx (1) (standard) 2090-CPWM7DF-xxAFxx (1) (continuous-flex) 2090-XXNPMF-xxSxx (standard) 2090-CPBM4DF-xxAFxx (continuous-flex) 2090-CPWM4DF-xxAFxx (continuous-flex) 2090-CPBM7DF-xxAAxx (1) (standard) 2090-CPBM7DF-xxAFxx (1) (continuous-flex) 2090-CPWM7DF-xxAAxx (1) (standard) 2090-CPWM7DF-xxAFxx (1) (continuous-flex) 2090-CPBM6DF-16AAxx (standard) 2090-CPWM6DF-16AAxx (standard) MP-Series (Bulletin MPL) MP-Series (Bulletin MPS) Circular DIN MPS-A/Bxxxx MP-Series (Bulletin MPAS) MPAS-A/Bxxxx MP-Series (Bulletin MPAR) MPAR-A/B1xxx and MPAR-A/B2xxx MP-Series (Bulletin MPM) MPM-A/Bxxxx MP-Series (Bulletin MPF) MPF-A/Bxxxx MP-Series (Bulletin MPAR) MPAR-A/B3xxx MP-Series (Bulletin MPAI) MPAI-A/Bxxxx TL-Series (Bulletin TLY) TL-Series (Bulletin TLAR) Circular Plastic TLY-Axxxx TLAR-Axxxx (1) You must remove the motor-side o-ring when using 2090-CPxM7DF-xxAxx cables. 62 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 This diagram shows an example of three-phase power wires for motors/actuators that have no brakes. Thermal switch wires are included in the feedback cable. Refer to Kinetix 350 Drive/Rotary Motor Wiring Examples beginning on page 146 for interconnect diagrams. Figure 35 - Motor Power Terminations (three-phase wires only) Motor Power (MP) Connector Plug Motor Cable Shield Clamp Kinetix 350 Drive The cable shield clamp shown above is mounted to the subpanel. Ground and secure the motor power cable in your system following instructions on page 66. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 63 Chapter 4 Connect the Kinetix 350 Drive System This diagram shows an example of wiring with three-phase power wires and brake wires. The brake wires have a shield braid (shown below as gray) that folds back under the cable clamp before the conductors are attached to the motor brake circuit. Thermal switch wires are included in the feedback cable. Refer to Kinetix 350 Drive/Rotary Motor Wiring Examples beginning on page 146 for interconnect diagrams. Figure 36 - Motor Power Terminations (three-phase and brake wires) 6 5 7 3 2 8 4 1 To Motor Item Description Item Description 1 (1) 24V power supply 5 I/O (IOD) connector(2) 2 (1) Relay and diode assembly (3) 6 2097-V3xPRx-LM Kinetix 350 drive 3 Minimize unshielded wires in brake circuit 7 Motor power (MP) connector 4 MP-Series cable brake wires 8 Cable clamp (4) (1) User supplied. Size as required by motor brake, See Motor Brake Currents on page 149. (2) Pin 43 and 44 are configured as MTR_ BRAKE+ and MTR_BRAKE- Common respectively. Wire the output as sourcing and set brake engage and disengage times for motor selected. Motor brake is active on enable. (3) Diode 1N4004 rated 1.0 A @ 400V DC. See Interconnect Diagram Notes beginning on page 141. (4) Exposed shield under clamp and place within 50…75 mm (2…3 in.) of drive, see page 66 for details. Cable shield and lead preparation is provided with most Allen-Bradley cable assemblies. Follow these guidelines if your motor power cable shield and wires require preparation. 64 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 Figure 37 - Cable Shield and Lead Preparation Strip Length (see table below) U Outer Insulation V W Motor Power Cable Exposed Braid 25.4 mm (1.0 in.) As required to have ground clamp within 50…75 mm (2…3 in.) of the drive. Refer to Shunt Resistor Wiring Example beginning on page 146 for interconnect diagrams. Table 24 - Motor Power (MP) Connector MP-Series or TL-Series Servo Motor Terminal U / Brown U V / Black V W / Blue W Green/Yellow Table 25 - Motor Power (MP) Termination Specifications Drive Cat. No. 2097-V31PR0-LM 2097-V31PR2-LM 2097-V32PR0-LM 2097-V32PR2-LM 2097-V32PR4-LM 2097-V33PR1-LM 2097-V33PR3-LM 2097-V33PR5-LM 2097-V34PR3-LM 2097-V34PR5-LM 2097-V34PR6-LM 2097-V33PR6-LM Terminals PE W V U Recommended Wire Size mm2 (AWG) 2.5 (14) Strip Length mm (in.) Torque Value N•m (lb•in) 7 (0.28) 0.5 (4.5) 4.0 (12) Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 65 Chapter 4 Connect the Kinetix 350 Drive System Apply the Motor Cable Shield Clamp This procedure assumes you have completed wiring your motor power (MP) connector and are ready to apply the cable shield clamp. Follow these steps to apply the motor cable shield clamp. 1. Locate a suitable position for installing cable shield clamp within 50…75 mm (2…3 in.) of the drive. Motor Power Ground Shield Clamp 25 (1.0) 34.0 (1.34) Dimensions are in mm (in.). 12.7 (0.50) 50…75 (2…3) 50…75 (2…3) If panel is painted, remove paint to provide metal-to-metal contact. 2. Lay out and drill holes for cable clamp. ATTENTION: Plan the installation of your system so that you can perform all cutting, drilling, tapping, and welding with the system removed from the enclosure. Because the system is of the open type construction, be careful to keep any metal debris from falling into it. Metal debris or other foreign matter can become lodged in the circuitry, which can result in damage to components. 3. Locate the position on the motor power cable that comes under the clamp and remove about an inch of the cable jacket to expose the shield braid. 4. Position the exposed portion of the cable braid directly in line with the clamp. 5. Clamp the exposed shield to the panel by using the clamp and two #6-32 x 1 screws provided. 6. Repeat step 1…step 5 for each Kinetix 350 drive you are installing. 66 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 Factory made cables with premolded connectors are designed to minimize EMI and are recommended over hand-built cables to improve system performance. However, other options are available for building your own feedback and I/O cables. Feedback and I/O Cable Connections Table 26 - Options for Connecting Motor Feedback and I/O Connection Option Cat. No. Cable Using This Type of Cable Premolded connectors N/A Motor feedback Refer to the table below for the premolded motor feedback cable available for your motor. Low-profile connector 2090-K2CK-D15M Motor feedback Refer to the table below for the flying-lead cable available for your motor. I/O Terminal Block 2097-TB1 I/O interface User-supplied flying-lead cable. Table 27 - Motor Feedback Cables for Specific Motor/Feedback Combinations Motor Cat. No. Feedback Type MPL-A/B15xxx-V/Ex4xAA, MPL-A/B2xxx-V/Ex4xAA High-resolution encoder MPL-A/B15xxx-Hx4xAA, MPL-A/B2xxx-Hx4xAA MPL-A/B3xxx-Hx7xAA, MPL-A/B4xxx-Hx7xAA, MPL-A/B45xxx-Hx7xAA MPL-A/B3xxx-M/Sx7xAA, MPL-A/B4xxx-M/Sx7xAA, MPL-A/B45xxx-M/Sx7xAA Feedback Cable Premolded Flying-lead N/A 2090-XXNFMF-Sxx (standard) 2090-CFBM4DF-CDAFxx (continuousflex) N/A 2090-XXNFMF-Sxx (standard) 2090-CFBM7DF-CDAFxx (1) (continuousflex) Incremental encoder High-resolution encoder 2090-CFBM7DF-CEAAxx (1) (standard) 2090-CFBM7DD-CEAAxx (1) (standard) 2090-CFBM7DD-CEAFxx (1) (continuous- 2090-CFBM7DF-CEAFxx (1) (continuousflex) flex) MPM-A/Bxxxxx-M/S MPF-A/Bxxxx-M/S MPAR-A/B3xxxx MPAI-A/Bxxxx High-resolution encoder MPS-A/Bxxxx-M/S MPAS-A/Bxxxx-V/A N/A 2090-XXNFMF-Sxx (standard) 2090-CFBM4DF-CDAFxx (continuousflex) 2090-CFBM6DD-CCAAxx (standard) 2090-CFBM6DF-CBAAxx (standard) MPAR-A/B1xxxx, MPAR-A/B2xxxx TLY-Axxxx-B TLAR-Axxxxx TLY-Axxxx-H High-resolution encoder Incremental encoder (1) You must remove the motor-side o-ring when using 2090-CPxM7DF-xxAxx cables. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 67 Chapter 4 Connect the Kinetix 350 Drive System Flying-lead Feedback Cable Pin-outs Table 28 - 2090-XXNFMF-Sxx or 2090-CFBMxDF-xxAxxx Feedback Cable High-resolution Feedback Connector Pin Incremental Feedback Drive MF Connector Pin 9V Encoder 5V Encoder 5V Encoder 1 Sin+ Sin+ AM+ 1 2 Sin- Sin- AM- 2 3 Cos+ Cos+ BM+ 3 4 Cos- Cos- BM- 4 5 Data+ Data+ IM+ 5 6 Data- Data- IM- 10 9 Reserved EPWR_5V EPWR_5V 14 10 Reserved ECOM ECOM 6 11 EPWR_9V Reserved Reserved 7 12 ECOM Reserved Reserved 6 13 TS+ TS+ TS+ 11 14 TS- TS- TS- – 15 Reserved Reserved S1 12 16 Reserved Reserved S2 13 17 Reserved Reserved S3 8 Table 29 - 2090-CFBM6DF-CBAAxx Feedback Cable High Resolution Incremental Feedback Connector Pin TLY-Axxxx-B TLAR-Axxxxx TLY-Axxxx-H Drive MF Connector Pin 6 BAT+ Reserved BAT+ AM+ 1 9 10 11 Reserved 12 2 BM+ 3 BM- 4 13 DATA+ IM+ 5 14 DATA- IM- 10 S1 12 S2 13 S3 8 15 17 Reserved 19 68 AM- 22 EPWR 5V EPWR 5V 14 23 ECOM and BAT- ECOM 6 24 Shield Shield Connector housing Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Wiring the Feedback and I/O Connectors Chapter 4 These procedures assume you have mounted your Kinetix 350 system, completed the power wiring, and are ready to connect motor feedback. Wire the I/O Connector Connect your I/O wires to the IOD connector by using the 2097-TB1 I/O Terminal Expansion Block. Refer to the Kinetix 300 I/O Terminal Expansion Block Installation Instructions, publication 2097-IN005. Figure 38 - Kinetix 350 Drive (IOD connector and terminal block) 1 30 2097-TB1 I/O Terminal Expansion Block 40 50 GND 11 12 20 21 I/O (IOD) Connector 29 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 69 Chapter 4 Connect the Kinetix 350 Drive System Wire the Low-profile Connector Kit The 2090-K2CK-D15M low-profile connector kit is suitable for terminating flying-lead motor feedback cables. Use it with the Kinetix 350 drive and all motors with incremental or high-resolution feedback. It has a 15-pin, male, Dsub connector and is compatible with all Bulletin 2090 feedback cables. TLY-Axxxx-B rotary motors and TLAR-Axxxxx electric cylinders also require the 2090-DA-BAT2 battery to back up the high-resolution encoder. Figure 39 - Kinetix 350 Drive (MF connector) Kinetix 350 Drive, Side View (2097-V33PR5-LM drive is shown) Kinetix 350 Drive, Front View (2097-V33PR5-LM drive is shown) 2090-K2CK-D15M Connector Kit with flying-lead feedback cable. Motor Feedback (MF) Connector Figure 40 - Wiring (15-pin) Flying-lead Feedback Cable Connections 2090-K2CK-D15M Connector Kit 15-pin (male) Motor Feedback Low-profile Connector Bare Wires Wire Insulation Foil Shield Pin 10 Pin 5 Mounting Screws Braided Shield Bulletin 2090 Feedback Cable Low Profile Connector Kit (2090-K2CK-D15M) Clamp Exposed Braid Under Clamp 3.6V battery (catalog number 2090-DA-BAT2) only required for use with TLY-Axxxx-B motors and TLAR-Axxx electric cylinders (high-resolution 17-bit encoders). Refer to Chapter 3 for feedback signal descriptions. Refer to Appendix B for the motor feedback interconnect drawing for your application. Tie Wrap Turn clamp over to hold small wires secure. Refer to Low Profile Connector Kit Installation Instructions, publication 2093-IN005, for connector kit specifications. 70 Pin 11 Pin 6 Pin 1 0 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 Outer Insulation Pin 15 Bulletin 2090 Feedback Cable Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Shunt Resistor Connections Chapter 4 Follow these guidelines when wiring your 2097-Rx shunt resistor. IMPORTANT When tightening screws to secure the wires, refer to the tables beginning on page 55 for torque values. IMPORTANT To improve system performance, run wires and cables in the wireways as established in Chapter 2. • Refer to Shunt Resistors on page 26 for noise zone considerations. • Refer to Shunt Resistor Wiring Example on page 145. • Refer to the installation instructions provided with your Bulletin 2097 shunt resistor, publication 2097-IN002. Figure 41 - Brake/DC Bus (BC) Connector B+ B+ BR BB- Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Front view is shown. Brake /DC Bus (BC) Connector 71 Chapter 4 Connect the Kinetix 350 Drive System Ethernet Cable Connections This guideline assumes you have your Logix Ethernet/IP module and Kinetix 350 drive mounted and ready to connect the network cables. IMPORTANT Connection to a larger network through an un-managed switch without Internet Group Management Protocol Snooping could cause degradation to the larger network. Network switches without IEEE-1588 will impact the overall system accuracy. However, for general time stamping this switch type is usually sufficient. Your overall network topology, number of connected nodes and choice of EtherNet switch affects motion performance. For more detailed information on designing your network, please consult the Converged Plantwide Ethernet Design & Implementation Guide, publication ENET-TD001. The EtherNet/IP network is connected by using the Port 1 connector. Refer to page 30 to locate the Ethernet connector on your Kinetix 350 drive. Refer to the figure below to locate the connector on your Logix communication module. Shielded Ethernet cable is available in lengths up to 78 m (256 ft). However, the total length of Ethernet cable connecting drive-to-drive, drive-to-controller, or drive-to-switch must not exceed 100 m (328 ft). If the entire channel is constructed of stranded cable (no fixed cable), then this is the equation for calculating maximum length: Maximum Length = (113-2N)/y, meters where N = the number of connections in the channel and y = the loss factor compared to fixed cable (typically 1.2…1.5). Figure 42 - CompactLogix Ethernet Port Location CompactLogix Controller Platform 1769-L33ERM Shown The Ethernet ports are on bottom of controller. The Port 1 Ethernet connection is used for connecting to a Logix controller and configuring your Kinetix 350 drive. 72 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Connect the Kinetix 350 Drive System Chapter 4 Figure 43 - Ethernet Wiring Example - External Switch CompactLogix Controller Platform 1769-L33ERM Shown 1783-US05T Stratix 2000 Switch 1 Personal Computer P W R 2 3 4 5 Kinetix 350 Drives Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 73 Chapter 4 Connect the Kinetix 350 Drive System Notes: 74 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Chapter 5 Configure and Start Up the Kinetix 350 Drive System Introduction This chapter provides procedures for configuring your Kinetix 350 system components with your ControlLogix® EtherNet/IP controller. Topic Page Introduction 75 Keypad Input 76 Configure the Kinetix 350 Drive Ethernet IP Address 79 Configure the Logix EtherNet/IP Controller 82 Apply Power to the Kinetix 350 Drive 91 Test and Tune the Axes 92 Disable EnableInputChecking Using a RSLogix Message Instruction 98 TIP Before you begin make sure you know the catalog number for the drive, the Logix controller, and the servo motor/actuator in your motion control application. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 75 Chapter 5 Configure and Start Up the Kinetix 350 Drive System Keypad Input The Kinetix 350 drive is equipped with a diagnostic status indicator and three push buttons that are used to select displayed information and to edit a limited set of parameter values. Parameters can be scrolled by using value, press After pressing . To return back to Scroll mode press . on editable parameters, the yellow status indicator D blinks indicating that the parameter value can be changed. Use value. Press . To view a to change the to store the new setting and return back to Scroll mode. Table 30 - Status Display Information 76 Status Indicator Description Hx.xx Hardware revision. For example, H2.00. Fx.xx Firmware revision. For example, F2.06. dHCP Ethernet DHCP Configuration: 0=’dHCP’ is disabled; 1=’dHCP’ is enabled. IP_1 Allows modification of the first octet of the IP address. IP_2 Allows modification of the second octet of the IP address. IP_3 Allows modification of the third octet of the IP address. IP_4 Allows modification of the fourth octet of the IP address. nEt1 Allows modification of the first octet of the netmask. nEt2 Allows modification of the second octet of the netmask. nEt3 Allows modification of the third octet of the netmask. nEt4 Allows modification of the fourth octet of the netmask. gat1 Allows modification of the first octet of the gateway. gat2 Allows modification of the second octet of the gateway. gat3 Allows modification of the third octet of the gateway. gat4 Allows modification of the fourth octet of the gateway. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 Status Indicators The Kinetix 350 drive has four status indicators and a four-digit display on the top front panel as shown below. These status indicators and the display are used to monitor the system status, activity, and troubleshoot faults. Figure 44 - Front Panel Display Table 31 - Status Indicators Status Indicator Function Description D Data entry Yellow status indicator will flash when changing. N Network state Indicates the state of the Network. See Network State Status Indicator on page 78. The bicolored status indicator shows red, green, or amber. M Module state Indicates the state of the Network. See Module State Status Indicator on page 77. The bicolored status indicator shows red, green, or amber. A Axis state Indicates the state of the Network. See Axis State Status Indicator on page 78. The bicolored status indicator shows red, green, or amber. Table 32 - Module State Status Indicator Status Indicator State Off Power off Flash red/green Drive self-testing Flashing green Standby Solid green Operational Flashing red Major recoverable fault Solid red Major unrecoverable fault Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 77 Chapter 5 Configure and Start Up the Kinetix 350 Drive System Table 33 - Axis State Status Indicator Status Indicator State Off Off Flash red/green Self test Off Initialization - bus not up Flashing green Initialization - bus up Off Shutdown - bus not up Flashing amber (1) Shutdown - bus up Off Pre-charge - bus not up Flashing amber (1) Flashing green (1) (2) Start inhibit Stopped Stopping Solid green (1) (2) Starting Running Testing Flashing red Solid red Aborting Major faulted Aborting Major faulted (1) The axis and the drive define minor fault conditions. While a minor fault does not affect the drive status indicator, it does affect the axis status indicator. When a minor fault condition is detected, a normally solid green status indicator indication changes to alternating red-green-red-green, a normally flashing green status indicator indication changes to alternating red-off-green-off, and a normally flashing amber indications changes to red-off-amber-off. (2) The drive also defines alarm conditions. When an alarm condition is detected, a normally solid green status indicator indication changes to alternating amber-green-amber green while a normally flashing green status indicator indication changes to alternating amber-off-green-off. Table 34 - Network State Status Indicator 78 Status Indicator State Steady off Not powered, no IP address Flashing green No connections Steady green Connected Flashing red Connection time-out Steady red Duplicate IP Flashing green and red Self-test Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Configure the Kinetix 350 Drive Ethernet IP Address Chapter 5 This section offers guidance on configuring your Ethernet connection to the Kinetix 350 drive. Ethernet Connection Configuration, programming, and diagnostics of the Kinetix 350 drive are performed over the standard 10/100 Mbps Ethernet communication port by using the RSLogix™ 5000 software. The Kinetix 350 drive and your personal computer must be configured to operate on the same Ethernet network. The IP addresses of the Kinetix 350 drive, the personal computer, or both drive and personal computer may require configuring to enable Ethernet communication between the two devices. IMPORTANT Any changes made to the Ethernet communication settings on the Kinetix 350 drive do not take effect until the drive is powered off and powered on again. Until the power is cycled the drive continues to use its previous settings. Kinetix 350 Drive Ethernet Port Configuration The IP address of the Kinetix 350 drive is composed of four sub-octets that are separated by three dots to conform to the Class C Subnet structure. Each suboctet can be configured with number between 1 and 254. As shipped from the factory the default IP address of a drive is 192.168.124.200. There are two methods of changing the current IP address. An address can be assigned to the drive automatically (dynamic IP address) when the drive is connected to a DHCP (Dynamic Host Configuration Protocol) enabled server, or you can manually assign an IP address to the drive (static IP address). Both methods of configuring the drive’s IP address are shown here. Obtain the Kinetix 350 Drives’ Current Ethernet Settings The current Ethernet setting and IP address of the Kinetix 350 drive can be obtained from the drive display and keypad. Press on the display and use to access parameters IP_1, IP_2, IP_3, and IP_4. Each of these parameters contain one sub-octet of the full IP address, for example in the case of the drive default (factory set) address parameters: IP_1 = 192 IP_2 = 168 IP_3 = 124 IP_4 = 200 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 79 Chapter 5 Configure and Start Up the Kinetix 350 Drive System By accessing these four parameters the full IP address on the drive can be obtained. If parameters IP_1, IP_2, IP_3, and IP_4 all contain ‘----‘ rather than a numerical values it means that the drive has DHCP enabled and the DHCP server is yet to assign the drive its dynamic IP address. As soon as an IP address is assigned by the server the address assigned is displayed by the drive in the above parameters. See Configure the IP Address Automatically (dynamic address) on page 81. Configure the IP Address Manually (static address) When connecting directly from the Kinetix 350 drive to the personal computer without a server or when connecting to a private network, where all devices have static IP addresses, assign the IP address of the Kinetix 350 drive manually. To assign the address manually, disable the DHCP mode. Do this by using the drive keypad and following these steps. 1. Press 2. Use . to access parameter DHCP. 3. Check this parameter is set to a value of 0. 4. If the DHCP parameter is set to 1 then use and to set to 0. 5. Cycle power to the drive. The change takes effect. When DHCP is disabled and power cycled to the drive, it reverts back to its previous static IP address. If you are connecting more than one drive to the personal computer create unique IP address for each drive. Do this by using the keypad on each drive to change the IP_4 parameter. IP_4 is the only octet that can be changed via the keypad. IP_1, IP2, and IP_3 are read-only accessed this way. The dive power must be cycled for any changes to take effect. 80 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 Configure the IP Address Automatically (dynamic address) When connecting a Kinetix 350 drive to a network domain with a DHCP enabled server the IP address of the Kinetix 350 drive is assigned automatically. To have the address assigned automatically the drive must have its DHCP mode enabled. Follow these steps using the drive keypad and display. 1. Press . 2. Use the to access parameter DHCP. 3. Check this parameter is set to 1. 4. If the DHCP parameter is set to 0, use to 1. and to set the parameter 5. Cycle power to the drive to make this change take effect. When the Kinetix 350 drive is waiting for an IP address to be assigned to it by the server it displays ‘----‘ in each of the four octet parameters (IP_1, IP_2, IP_3, and IP_4) on its display. Once the address is assigned by the server it appears in these parameters. If this parameter continues to display ‘----‘ then it is likely that a connection between the drive and server has not been established, or the server is not DHCP enabled. DHCP can be enabled through the RSLogix 5000 software. If you choose to configure the drive by using a manual (static) IP address, you can switch over to an automatic (dynamic) address once configuration is complete. See Obtain the Kinetix 350 Drives’ Current Ethernet Settings on page 79 for information on enabling DHCP from within the RSLogix 5000 software. TIP A useful feature of the RSLogix 5000 software and communication interface to the Kinetix 350 drive is the ability to assign the drive a name (text string). This name can then be used to discover the drive’s IP address and is useful when the drive has its IP address assigned automatically by the server for easy connection. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 81 Chapter 5 Configure and Start Up the Kinetix 350 Drive System Configure the Logix EtherNet/IP Controller This procedure assumes that you have wired your Kinetix 350 drive system and are using RSLogix 5000 software version 20.xx or later. For help using RSLogix 5000 software as it applies to configuring the ControlLogix EtherNet/IP controller, refer to Additional Resources on page 8. Configure the Logix Controller Follow these steps to configure the Logix controller. 1. Apply power to your Logix controller containing the EtherNet/IP port and open your RSLogix 5000 software. 2. From the File menu, choose New. The New Controller dialog box opens. 3. Configure the new controller. a. From the Type pull-down menu, choose the controller type. b. From the Revision pull-down menu, choose the revision. c. Type the file Name. 4. Click OK. 5. From the Edit menu, choose Controller Properties. 82 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 The Controller Properties dialog box opens. 6. Click the Date/Time tab. 7. Check Enable Time Synchronization. This will permit the controller to participate in the ControlLogix Time Synchronization or CIP Sync. The controller will also participate in an election in the Logix system for the best GrandMaster clock. 8. Click OK. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 83 Chapter 5 Configure and Start Up the Kinetix 350 Drive System Configure the Kinetix 350 Drive IMPORTANT To configure Kinetix 350 drive (catalog numbers 2097-V3xPRx-LM) you must be using RSLogix 5000 software, version 20 or later. Follow these steps to configure the Kinetix 350 drive. 1. Right-click the Logix EtherNet/IP controller you just created and choose New Module. The Select Module dialog box opens. 2. Clear the Module Type Category Filter and check the Drive and Motion catagories. 3. Select your 2097-V3xPRx-LM drive as appropriate for your actual hardware configuration and click Create. 84 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 The New Module dialog box opens. 4. Configure the new drive. a. Type the drive Name. b. Click an Ethernet Address option. In this example, the Private Network address is selected. c. Enter the address of your EtherNet/IP drive. In this example, the last octet of the address is 1. This must match the base node address of the drive. 5. Click Change in the Module Definition area. The Module Definition dialog box opens. 6. From the Power Structure pull-down menu, choose the Bulletin 2097 drive appropriate for your application. In the example, the 2097-V3xPRx-LM module is chosen. 7. Click OK to close the Module Definition dialog box. 8. Click OK to close the Module Properties dialog box. The 2097-V3xPRx-LM drive appears under the EtherNet/IP module in the I/O Configuration folder. 9. Right-click the 2097-V3xPRx-LM module you just created and choose Properties. The Module Properties dialog box opens. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 85 Chapter 5 Configure and Start Up the Kinetix 350 Drive System 10. Click the Associated Axes tab. 11. Click New Axis. The New Tag dialog box opens. 12. Type the axis Name. AXIS_CIP_DRIVE is the default Data Type. 13. Click Create. The new axis (Axis_1) appears under Motion Groups>Ungrouped Axes in the Controller Organizer and is assigned as Axis 1. 14. Click Apply. 86 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 Configure the Motion Group Follow these steps to configure the motion group. 1. Right-click Motion Groups in the Controller Organizer and choose New Motion Group. The New Tag dialog box opens. 2. Type the new motion group Name. 3. Click Create. The new motion group appears under the Motion Groups folder. 4. Right-click the new motion group and choose Properties. The Motion Group Properties dialog box opens. 5. Click the Axis Assignment tab and move your axes (created earlier) from Unassigned to Assigned. 6. Click the Attribute tab and edit the default values as appropriate for your application. 7. Click OK. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 87 Chapter 5 Configure and Start Up the Kinetix 350 Drive System Configure Axis Properties Follow these steps to configure axis properties. 1. Right-click an axis in the Controller Organizer and choose Properties. 2. Click the Motor category. The Motor Device Specification dialog box opens. 3. From the Data Source pull-down menu, choose Catalog Number. 4. Click Change Catalog. The Change Catalog Number dialog box opens. 5. Select the motor catalog number appropriate for your application. To verify the motor catalog number, refer to the motor name plate. 6. Click OK to close the Change Catalog Number dialog box. 88 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 7. Click Apply. Motor data specific to your motor appears in the Motor category. 8. Click the Scaling category and edit the default values as appropriate for your application. 9. Click Apply, if you make changes. 10. Click the Load category and edit the default values as appropriate for your application. 11. Click Apply, if you make changes. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 89 Chapter 5 Configure and Start Up the Kinetix 350 Drive System 12. Click the Actions category. The Actions to Take Upon Conditions dialog box opens. From this dialog box, you can program actions and change the action for exceptions (faults). Refer to Logix Controller and Drive Behavior on page 205 for more information. 13. Click Parameters. The Motion Axis Parameters dialog box opens. From this dialog box you can set delay times for servo motors. For recommended motor brake delay times, refer to the Kinetix Motion Control Selection Guide, publication GMC-SG001. 14. Click OK. 15. Verify your Logix program and save the file. 90 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 Download the Program After completing the Logix configuration you must download your program to the Logix processor. Apply Power to the Kinetix 350 Drive This procedure assumes that you have wired and configured your Kinetix 350 drive system and your Ethernet/IP interface controller. SHOCK HAZARD: To avoid hazard of electrical shock, perform all mounting and wiring of the Bulletin 2097 drive prior to applying power. Once power is applied, connector terminals may have voltage present even when not in use. Follow these steps to apply power to the Kinetix 350 drive system. 1. Disconnect the load to the motor. ATTENTION: To avoid personal injury or damage to equipment, disconnect the load to the motor. Make sure each motor is free of all linkages when initially applying power to the system. 2. Determine the source of the drive logic power. If Your Logic Power Then Is from (24V DC) back-up power Apply (24V DC) back-up power to the drive (BP connector). Mains input power Apply 120, 240,or 460V AC mains input power to the drive (IPD connector). 3. Apply 120, 240, or 460V AC mains input power to the Kinetix 350 drive IPD connector. 4. Observe the four digit status indicator. Data Entry Status Indicator Four Character Status Indicator If the status indicator is Then -00- Go to step 5 Blank Go back to main step 2 5. If Your Logic Power Then Is from (24V DC) back-up power Apply 120, 240, or 460V AC mains input power to the drive (IPD connector) Mains input power Go to step 5 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 91 Chapter 5 Configure and Start Up the Kinetix 350 Drive System 6. If drive ENABLE is Then Hard wired Apply 24V DC Not used Disable enableInputChecking using procedure on page 98 7. Observe the status indicator on the front of the Kinetix 350 drive. Status Indicator Module Axis Network Test and Tune the Axes Condition Status Do This Steady green Operational condition Observe the Axis, status indicator page 77 Steady or flashing red Drive is faulted Go to Module State Status Indicator on page 77 Steady green or amber, flashing Operational condition Observe the Network, status indicator page 77 Steady or flashing red Axis is faulted Go to Axis State Status Indicator on page 78 Steady green Communication is ready Go to Test and Tune the Axes on page 92 Any state other than steady green Communication error Go to Network State Status Indicator on page 78 This procedure assumes that you have configured your Kinetix 350 drive, your ControlLogix EtherNet/IP controller, and applied power to the system. IMPORTANT Before proceeding with testing and tuning your axes, verify that the drive status indicators are operating as described in Status Indicators on page 117. For help using RSLogix 5000 software as it applies to testing and tuning your axes with ControlLogix EtherNet/IP controller, refer to Additional Resources on page 8. Test the Axes Follow these steps to test the axes. 1. Verify the load was removed from each axis. 2. Right-click an axis in your Motion Group folder and choose Properties. The Axis Properties dialog box opens. 92 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 3. Click the Hookup Tests category. 4. Type 2.0 as the number of revolutions for the test or another number more appropriate for your application. This Test Performs this Test Marker Verifies marker detection capability as you rotate the motor shaft. Motor Feedback Verifies feedback connections are wired correctly as you rotate the motor shaft. Motor and Feedback Verifies motor power and feedback connections are wired correctly as you command the motor to rotate. If drive ENABLE is Then Hard wired Apply 24V DC Not used Disable enableInputChecking using procedure on page 98 5. ATTENTION: To avoid personal injury or damage to equipment, apply 24V ENABLE signal only to the axis you are testing. 6. Click the desired tab (Marker/Motor Feedback/Motor and Feedback). In this example, the Motor and Feedback test is chosen. 7. Click Start. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 93 Chapter 5 Configure and Start Up the Kinetix 350 Drive System The RSLogix 5000 - Motor and Feedback Test dialog box opens. The Test State is Executing. When the test completes successfully, the Test State changes from Executing to Passed. 8. Click OK. This dialog box opens asking if the direction was correct. 9. Click Yes. If the test fails, this dialog box opens. a. Click OK. b. Verify the Axis status indicator turned solid green during the test. c. Verify that the drive ENABLE signal is applied to the axis you are testing or that the enableInputChecking attribute is set to zero. d. Verify the unit values entered in the Scaling category. e. Return to main step 6 and run the test again. 94 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 Tune the Axes This is a basic procedure for simple systems. If you have a complicated system refer to CIP Motion Configuration and Startup User Manual, publication Motion-UM003. Follow these steps to tune the axes. 1. Verify the load is still removed from the axis being tuned. ATTENTION: To reduce the possibility of unpredictable motor response, tune your motor with the load removed first, then re-attach the load and perform the tuning procedure again to provide an accurate operational response. 2. Click the Autotune category. 3. Type values for Travel Limit and Speed. In this example, Travel Limit = 5 and Speed = 10. The actual value of programmed units depend on your application. 4. From the Direction pull-down menu, choose a setting appropriate for your application. Forward Uni-directional is default. 5. Edit other fields as appropriate for your application and click Apply. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 95 Chapter 5 Configure and Start Up the Kinetix 350 Drive System 6. If drive ENABLE is Then Hard wired Apply 24V DC Not used Disable enableInputChecking using procedure on page 98 ATTENTION: To avoid personal injury or damage to equipment, apply 24V ENABLE signal only to the axis you are testing. 7. Click Start. The RSLogix - Autotune dialog box opens. When the test completes, the Test State changes from Executing to Success. Tuned values populate the Loop and Load parameter tables. Actual bandwidth values (Hz) depend on your application and may require adjustment once motor and load are connected. At this point, you can compare existing and tuned values for your gains and inertias with the prospective tune values. 8. Accept the new values and apply them to the controller. Now you can run the system with the new gain set and evaluate performance. You can improve the performance by adjusting application type, loop response, and/or load coupling selections. TIP If your application requires stricter performance you can further improve performance with manual tuning. 9. Click OK to close the RSLogix 5000 - Autotune dialog box. 10. Click OK to close the Axis Properties dialog box. 96 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Configure and Start Up the Kinetix 350 Drive System Chapter 5 11. If the test fails, this dialog box opens. a. Click OK. b. Make an adjustment to motor velocity. c. Refer to the appropriate Logix motion module user manual for more information. d. Return to step 7 and run the test again. 12. Repeat Test and Tune the Axes for each axis. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 97 Chapter 5 Configure and Start Up the Kinetix 350 Drive System Disable EnableInputChecking Using a RSLogix Message Instruction This procedure sends a Logix message to disable the EnableInputChecking attribute in the Kinetix 350 drive. 1. From the Controller Organizer, choose Tasks>MainTask>MainProgram>MainRoutine. 2. Create a MSG instruction rung as shown. 3. Set the values in the Message Configuration as shown. 4. Click the Communications tab and browse to the drive tag, in this case K350, as shown. 5. When the program is in Run mode, trigger the rung to run the instruction. The drive will not check the enable input signal on IOD-29 Enable to IOD -26 Common. This MSG instruction only needs to be executed once as it is a persistent type instruction and gets saved to the drive Non-volatile Memory. To re-enable enable input signal checking on IOD-29 Enable to IOD-26 Common, change the Source Element register, enableinputChecking from 0 to 1 and trigger the run again. 98 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Chapter 6 Kinetix 350 Drive Safe Torque-off Feature Introduction This chapter introduces you to how the safe torque-off feature meets the requirements for ISO 13849-1 performance level d (PLd) safety category 3. Topic Page Introduction 99 Certification 100 Description of Operation 101 Functional Proof Tests 101 PFD and PFH Definitions 102 PFD and PFH Data 102 Safe Torque-off Connector Data 103 Wiring Your Safe Torque-off Circuit 104 Kinetix 350 Drive Safe Torque-off Feature 106 Kinetix 350 Drive Safe Torque-off Wiring Diagrams 107 Safe Torque-off Signal Specifications 108 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 99 Chapter 6 Kinetix 350 Drive Safe Torque-off Feature Certification The safe torque-off circuit is type-approved and certified for use in safety applications up to and including ISO 13849-1 performance level d (PLd) safety category 3. The TÜV Rheinland group has approved the Kinetix 350 drives for use in safetyrelated applications up to ISO 13849-1 performance level d (PLd) safety category 3, in which the de-energized state is considered to be the safe state. All of the examples related to I/O included in this manual are based on achieving deenergization as the safe state for typical machine safety systems. Important Safety Considerations The system user is responsible for the following: • Validation of any sensors or actuators connected to the drive system • Completing a machine-level risk assessment • Certification of the machine to the desired ISO 13849-1 performance level • Project management and proof testing • Programming the application software and the device configurations in accordance with the information in this safety reference manual and the drive product manual Safety Category 3 Requirements Safety-related parts are designed with these attributes: • A single fault in any of these parts does not lead to the loss of the safety function • A single fault is detected whenever reasonably practicable • Accumulation of undetected faults can lead to the loss of the safety function. Stop Category Definition Stop category 0 is achieved with immediate removal of power to the actuator. IMPORTANT 100 In the event of drive or control failure, the most likely stop category is category 0. When designing the machine application, consider timing and distance for a coast to stop. For more information regarding stop categories, refer to EN 60204-1. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Safe Torque-off Feature Chapter 6 Performance Level and Safety Integrity Level (SIL) CL2 For safety-related control systems, Performance Level (PL), according to ISO 13849-1, and SIL levels, according to EN 61508 and EN 62061, include a rating of the systems ability to perform its safety functions. All of the safety-related components of the control system must be included in both a risk assessment and the determination of the achieved levels. Refer to the ISO 13849-1, EN 61508, and EN 62061 standards for complete information on requirements for PL and SIL determination. Description of Operation The safe torque-off feature provides a method, with sufficiently low probability of failure on demand, to force the power-transistor control signals to a disabled state. When disabled, or any time power is removed from the safety enable inputs, all of the drives output-power transistors are released from the ON state, effectively removing motive power generated by the drive. This results in a condition where the motor is in a coasting condition (stop category 0). Disabling the power transistor output does not provide mechanical isolation of the electrical output, which may be required for some applications. Under normal drive operation, the safe torque-off switches are energized. If either of the safety enable inputs are de-energized, the gate control circuit is disabled. To meet ISO 13849-1 (PLd) both safety channels must be used and monitored. ATTENTION: Permanent magnet motors may, in the event of two simultaneous faults in the IGBT circuit, result in a rotation of up to 180 electrical degrees. Functional Proof Tests The functional safety standards require that functional proof tests be performed on the equipment used in the system. Proof tests are performed at user-defined intervals, not to exceed one year, and are dependent upon PFD and PFH values. IMPORTANT Users specific applications determine the time frame for the proof test interval, but it must not exceed one year due to the use of switches internal to the drive, as required by ISO 13849-1. To proof test the safe torque-off function, you must interrupt power to the inputs of the safe torque-off function at pins STO-4 and STO-6 and verify that the drive is in the disabled state. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 101 Chapter 6 Kinetix 350 Drive Safe Torque-off Feature Table 35 - Proof Test Truth Table Safety Function State Safety Input 1 (STO-4) Safety Input 2 (STO-6) Safety Status Output (STO-3) Normal operation Energized Energized Energized Energized De-energized Energized De-energized Energized Energized De-energized De-energized De-energized Safe torque-off mismatch Safe torque-off function engaged Normal operation of the safe torque-off function, if monitored and verified, constitutes the proof test. Troubleshooting the Safe Torque-off Function ATTENTION: The safe torque-off fault is detected upon demand of the safe torque-off function. After troubleshooting, a proof test must be performed to verify correct operation. PFD and PFH Definitions Safety-related systems can be classified as operating in either a Low Demand mode, or in a High Demand/Continuous mode: • Low Demand mode: where the frequency of demands for operation made on a safety-related system is no greater than one per year or no greater than twice the proof-test frequency. • High Demand/Continuous mode: where the frequency of demands for operation made on a safety-related system is greater than once per year or greater than twice the proof test interval. The SIL value for a low demand safety-related system is directly related to orderof-magnitude ranges of its average probability of failure to satisfactorily perform its safety function on demand or, simply, average probability of failure on demand (PFD). The SIL value for a High Demand/Continuous mode safety-related system is directly related to the probability of a dangerous failure occurring per hour (PFH). PFD and PFH Data These PFD and PFH calculations are based on the equations from EN 61508 and show worst-case values. This table provides data for a 20-year proof test interval and demonstrates the worst-case effect of various configuration changes on the data. Table 36 - PFD and PFH for 20-year Proof Test Interval 102 Attribute Value PFH [1e-9] 5.9 PFD [1e-3] 1.0 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Safe Torque-off Feature Safe Torque-off Connector Data Chapter 6 This section provides safe torque-off (STO) connector and header information for the Kinetix 350 drive safe torque-off. STO Connector Pinouts Headers extend the STO connector signals for use in wiring or to defeat (not use) the safe torque-off function. Figure 45 - 6-pin Safe Torque-off (STO) Connector 1 2 3 4 5 6 STO Safe Torque-off (STO) Connector Kinetix 350 Drive, Bottom View (2097-V32PR4-LM is shown) STO Pin Description Signal 1 +24V DC output from the drive +24V DC control 2 +24V DC output common Control COM 3 Safety status Safety Status 4 Safety input 1 (+24V DC to enable) Safety Input 1 5 Safety common Safety COM 6 Safety input 2 (+24V DC to enable) Safety Input 2 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 103 Chapter 6 Kinetix 350 Drive Safe Torque-off Feature Wiring Your Safe Torque-off Circuit This section provides guidelines for wiring your Kinetix 350 safe torque-off drive connections. European Union Directives If this product is installed within the European Union or EEC regions and has the CE mark, the following regulations apply. For more information on the concept of electrical noise reduction, refer to System Design for Control of Electrical Noise Reference Manual, publication GMC-RM001. EMC Directive This unit is tested to meet Council Directive 2004/108/EC Electromagnetic Compatibility (EMC) by using these standards, in whole or in part: • EN 61800-3 - Adjustable Speed Electrical Power Drive Systems, Part 3 - EMC Product Standard including specific test methods • EN 61000-6-4 EMC - Emission Standard, Part 2 - Industrial Environment • EN 61000-6-2 EMC - Immunity Standard, Part 2 - Industrial Environment The product described in this manual is intended for use in an industrial environment. CE Conformity Conformity with the Low Voltage Directive and Electromagnetic Compatibility (EMC) Directive is demonstrated by using harmonized European Norm (EN) standards published in the Official Journal of the European Communities. The safe torque-off circuit complies with the EN standards when installed according instructions found in this manual. CE Declarations of Conformity are available online at: http://www.rockwellautomation.com/products/certification/ce. Low Voltage Directive These units are tested to meet Council Directive 2006/95/EC Low Voltage Directive. The EN 60204-1 Safety of Machinery-Electrical Equipment of Machines, Part 1-Specification for General Requirements standard applies in whole or in part. Additionally, the standard EN 50178 Electronic Equipment for use in Power Installations apply in whole or in part. 104 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Safe Torque-off Feature Chapter 6 Safe Torque-off Wiring Requirements These are the safe torque-off (STO) wiring requirements. Wire should be copper with 75 °C (167 °F) minimum rating. IMPORTANT The National Electrical Code and local electrical codes take precedence over the values and methods provided. IMPORTANT Stranded wires must terminate with ferrules to prevent short circuits, per table D7 of EN 13849. Figure 46 - Safe Torque-off (STO) Terminal Plug 1 2 5 6 3 4 ol contr V DC M 4 2 + rol CO Cont tus y sta Safet ty input 1 Safe ty COM 2 Safe ty input Safe Table 37 - Safe Torque-off (STO) Terminal Plug Wiring Safe Torque-off (STO) Connector Recommended Wire Size Pin Signal Stranded Wire with Ferrule mm2 (AWG) STO-1 STO-2 STO-3 STO-4 STO-5 STO-6 +24V DC Control Control COM Safety Status Safety Input 1 Safety COM Safety Input 2 0.75 (18) Solid Wire mm2 (AWG) 1.5 (16) Strip Length mm (in.) Torque Value N•m (lb•in) 6 (0.25) 0.2 (1.8) IMPORTANT Pins STO-1 (+24V DC Control) and STO-2 (Control COM) are used only by the motion-allowed jumpers to defeat the safe torque-off function. When the safe torque-off function is in operation, the 24V supply must come from an external source. IMPORTANT To be sure of system performance, run wires and cables in the wireways as established in the user manual for your drive. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 105 Chapter 6 Kinetix 350 Drive Safe Torque-off Feature Kinetix 350 Drive Safe Torque-off Feature The safe torque-off circuit, when used with suitable safety components, provides protection according to ISO 13849-1 (PLd). The safe torque-off option is just one safety control system. All components in the system must be chosen and applied correctly to achieve the desired level of operator safeguarding. The safe torque-off circuit is designed to safely remove power from the gate firing circuits of the drives output power devices (IGBTs). This prevents them from switching in the pattern necessary to generate AC power to the motor. You can use the safe torque-off circuit in combination with other safety devices to meet the stop and protection-against-restart requirements of ISO 13849-1. ATTENTION: This option is suitable for performing mechanical work on the drive system or affected area of a machine only. It does not provide electrical safety. SHOCK HAZARD: In Safe Torque-off mode, hazardous voltages may still be present at the motor. To avoid an electric shock hazard, disconnect power to the motor and verify that the voltage is zero before performing any work on the motor. Safe Torque-off Feature Bypass The drive is supplied from the factory with the safe torque-off circuit enabled. The drive is not operational until +24V is present at terminals STO-4 and STO-6. When safety connections are not required, the drive can be operated with the safety circuit disabled. Use jumper wires, as shown, to defeat the safe torque-off function. Figure 47 - STO Motion-allowed Jumpers STO-1 STO-2 STO-3 STO-4 STO-5 STO-6 IMPORTANT 106 Pins STO-1 (+24V DC Control) and STO-2 (Control COM) are used only by the motion-allowed jumpers to defeat the safe torque-off function. When the safe torque-off function is in operation, the 24V supply must come from an external source. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Kinetix 350 Drive Safe Torque-off Feature Kinetix 350 Drive Safe Torque-off Wiring Diagrams Chapter 6 This section provides typical wiring diagrams for the Kinetix 350 drive safe torque-off feature with other Allen-Bradley safety products. For additional information regarding Allen-Bradley safety products, including safety relays, light curtain, and gate interlock applications, refer to the Safety Products Catalog, website http://www.ab.com/catalogs. The drive is shown in a single-axis relay configuration for category 0 stop per EN-60204-1 Safety of Machinery Directive. These are examples, however, and user applications can differ based on the required overall machine performance level requirements. IMPORTANT The Kinetix 350 drive meets the requirements of ISO 13849-1 Safety of Machinery, Safety-related Parts of Control Systems, category (CAT 3), performance level (PL)d and Safety Integrity Level (SIL) 2 per EN 61800-52:2007. Dual inputs and drive monitoring of the safe torque-off circuit, STO-4 and ST0-6, are done to prevent drive enable should either or both of these inputs not function. It is suggested to evaluate the entire machine performance level required with a risk assessment and circuit analysis. Contact your local distributor or Rockwell Automation Sales for more information. Figure 48 - Single-axis Relay Configuration (Stop Category 0) with Automatic Reset External +24V DC Kinetix 350 Drive Safe Torque-off Demand A1 S11 S52 S12 13 23 33 41 Allen-Bradley Monitoring Safety Relay MSR127RP (440R-N23135) S21 S22 S34 A2 Auxiliary Signal to PLC 14 24 34 42 External 24V COM Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Safe Torque-off (STO) Connector with Wiring Header 1 2 3 4 5 6 +24V DC COM Status Safety Input 1 Safety Common Safety Input 2 107 Chapter 6 Kinetix 350 Drive Safe Torque-off Feature Safe Torque-off Signal Specifications This table provides specifications for the safe torque-off signals used in the Kinetix 350 servo drives. Attribute Value Insulated, compatible with single-ended output (+24V DC) Safety inputs (1) Enable voltage range: 20…24V DC Disable voltage range: 0…1.0V DC Input impedance 6.8 k Safety status Isolated Open Collector (Emitter is grounded.) Output load capability 100 mA Digital outputs max voltage 30V DC (1) Safety inputs are not designed for pulse testing. 108 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Chapter 7 Troubleshoot the Kinetix 350 Drive Introduction Safety Precautions This chapter provides troubleshooting tables for your Kinetix 350 drive. Topic Page Introduction 109 Safety Precautions 109 Interpret Status Indicators 110 General System Behavior 119 Logix Controller and Drive Behavior 121 Web Server Interface 125 Observe the following safety precautions when troubleshooting your Kinetix 350 drive. ATTENTION: Capacitors on the DC bus may retain hazardous voltages after input power has been removed. Before working on the drive, measure the DC bus voltage to verify it has reached a safe level or wait the full time interval as indicated in the warning on the front of the drive. Failure to observe this precaution could result in severe bodily injury or loss of life. ATTENTION: Do not attempt to defeat or override the drive fault circuits. You must determine the cause of a fault and correct it before you attempt to operate the system. Failure to correct the fault could result in personal injury and/or damage to equipment as a result of uncontrolled machine operation. ATTENTION: Provide an earth ground for test equipment (oscilloscope) used in troubleshooting. Failure to ground the test equipment could result in personal injury. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 109 Chapter 7 Troubleshoot the Kinetix 350 Drive Interpret Status Indicators Refer to these troubleshooting tables to identify faults, potential causes, and the appropriate actions to resolve the fault. If the fault persists after attempting to troubleshoot the system, please contact your Rockwell Automation sales representative for further assistance. Four-digit Display Messages The control modules include a four-digit seven-segment display for status and fault messages. The display scrolls to display text strings. The Four-digit Display Messages table lists the messages along with their priorities. When messages of different priorities need to be displayed, for example, when the drive has both a fault and a start inhibit, only the higher priority message is displayed. When messages of equal priority are needed, for example, when there is more than one fault, the messages are displayed in a round-robin fashion. Only two messages will be scrolled in this manner.When a fault is annunciated, the entire fault text will scroll on the display regardless of when the fault is cleared The IP address is always an active condition, meaning that it will scroll in conjunction with the axis state as long as there are no higher priority messages to display. Refer to the table on Four-digit Display Messages for a description of the messages that scroll across the display during powerup. Table 38 - Four-digit Display Messages 110 Device Condition Display Digit IP address (always active) xxx.xxx.xxx.xxx Executing device self-test -08- Waiting for connection to controller -00- Configuring device attributes -01- Waiting for group synchronization -02- Waiting for DC Bus to charge -03- Device is operational -04- Start inhibit code S xx Start inhibit code - custom Scxx Axis fault code F xx Axis fault code - custom Fcxx Boot error Lxxx Power on Self Test (POST) error Pxxx Initialization fault code - custom Icxx Node fault code nFxx Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Priority (lower is higher) 4 3 2 1 1 Troubleshoot the Kinetix 350 Drive Chapter 7 Fault Codes These fault code tables are designed to help you resolve anomalies. When a fault is detected, the four-digit status indicator scrolls the display message. This is repeated until the fault code is cleared. Table 39 - Fault Code Summary Fault Code Type S xx Scxx F xx Fcxx Description Conditions that prevent the drive from enabling, see Table 40. Standard axis fault, see Table 41 and Table 42. Lxxx Unrecoverable errors that occur during the boot process. Return drive to Rockwell Automation. Pxxx Unrecoverable errors that occurred during the Power on Self Test (POST). Return drive to Rockwell Automation. Icxx Anomalies that prevent normal operation and occur during the initialization process. nFxx Anomalies that prevent normal operation of the drive. Node Fault. This type of fault that impacts the servo drive not just the axis of motion. Table 40 - S xx and Scxx Start Inhibit Codes RSLogix 5000 Fault Message Problem or Symptom S 01 Axis enable input. The axis enable input is deactivated. S 02 Motor not configured. The associated motor has not been configured for use. Four-digit Display Potential Cause Possible Resolution Axis Enable Input is not active. • Check wiring and 24V source for drive ENABLE Input. • Disable enableInputChecking attribute using a message instruction. • Cycle power or reset the drive. • Check proper motor has been selected in RSLogix software. • Replace motor if faulting continues. • Apply 24V sources to safety circuit. • Use jumpers to bypass safety circuit. S 03 Feedback not configured. The associated feedback device has not been configured for use or the configuration does not match what is connected. Faulty intelligent encoder or incorrect motor file. Sc05 Safe torque off. No power or safety circuitry not configured. The safety function has disabled the power structure. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 111 Chapter 7 Troubleshoot the Kinetix 350 Drive Table 41 - F xx Fault Codes Four-digit Display RSLogix 5000 Fault Message Problem or Symptom Potential Cause Possible Resolution F 02 Illegal Hall State State of Hall feedback inputs is incorrect. Improper connections. • • Check wiring of S1,S2, and S3 Check the power supply to the encoder. F 03 Motor Overspeed Motor speed has exceeded 125% of maximum rated speed. • • • Check motor wire phasing. Check cables for noise. Check tuning. • Check motor wiring at motor feedback (MF) connector. Check TS+ and COM wiring. Operate within (not above) the continuous torque rating for the ambient temperature. Lower ambient temperature or increase motor cooling. Verify the proper motor has been selected. F 05 Motor Overtemperature The motor thermostat, motor thermistor, or encoder temperature sensor indicates that the motor factory temperature limit has been exceeded. • • High motor ambient temperature and/or Excessive Current. • • F 07 F 10 F 11 F 13 112 Motor Thermal Protection Inverter Overcurrent Inverter Overtemperature Inverter Thermal Protection The thermal model for the motor indicates that the temperature has exceeded 110% of its rating. The drive fault output indicates that the power transistors were turned off because of overcurrent, overtemperature, or power supply problems. Inverter thermal switch tripped. The thermal model for the power transistors indicates that the temperature has exceeded 110% of its rating. The machine duty cycle requires an RMS current exceeding the continuous rating of the motor. Change the command profile to reduce speed or increase time. Motor cables shorted. Verify continuity of motor power cable and connector. Motor winding shorted internally. Disconnect motor power cables from the motor. Use multimeter to check that the resistance of phase-to-phase is not open and that phase-to-ground is open. The drive temperature is too high. • Check for clogged vents or defective fan. • Make sure cooling is not restricted by insufficient space around the unit. • Verify ambient temperature is is within the specification. See Environmental Specifications on page 133. Operation above continuous power rating and/or product environmental ratings. • • Operate within the continuous power rating. Reduce acceleration rates. The drive has a short circuit, overcurrent, or failed component. Remove all power and motor connections, and preform a continuity check from the DC bus to the U, V, and W motor outputs. If a continuity exists, check for wire fibers between terminals, or send drive in for repair. Loss of TTL signal Check AM+, AM -, BM +, and BMsignals. Drive fan failed. Replace the failed drive. The cabinet ambient temperature is above rating. Check the cabinet temperature. See Environmental Specifications on page 133 The machine duty cycle requires an RMS current exceeding the continuous rating of the controller. Change the command profile to reduce speed or increase time. The airflow access to the drive system is limited or blocked. Check airflow and re-route cables away from the drive system. The machine duty cycle requires an RMS current exceeding the continuous rating of the controller. Change the command profile to reduce speed or increase time. Motor brake on. Turn motor brake off. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Troubleshoot the Kinetix 350 Drive Chapter 7 Table 41 - F xx Fault Codes (continued) Four-digit Display F 33 F 35 RSLogix 5000 Fault Message Bus Undervoltage Bus Overvoltage Problem or Symptom Potential Cause Possible Resolution • With three-phase power present, the DC bus voltage is below limits. DC bus voltage for 460V system is below 275V. DC bus voltage for 230V system is below 137V. DC bus voltage for 120V system is below 80V The DC bus voltage is measured above a factory limit. • On sin/cos encoders, the sum of the square of the sin/cos signals has been measured below a factory limit. On TTL encoders, the absolute value of the differential A/B signals is below a factory limit. F 43 Feedback Loss F 45 Feedback Serial Comms (TL-Series motors and actuators only) The number of consecutive missed or corrupted serial data packets from the feedback device has exceeded a factory set limit. F 47 Feedback Self Test The feedback device has detected an internal error. F 50 Hardware Overtravel - Positive Axis moved beyond the physical travel limits in the positive direction. F 51 F 54 Hardware Overtravel - Negative Excessive Position Error • Axis moved beyond the physical travel limits in the negative direction. • • Excessive regeneration of power. Change the deceleration or motion profile. When the motor is driven by an external mechanical power source, it may regenerate too much peak energy through the drive power supply. The system faults to save itself from an overload. Use a larger system (motor and drive). DC bus voltage for 460V system is over 820V. Install shunt resistor. • • Check motor encoder wiring. Run Hookup test in RSLogix 5000 software. Communication was not established with an intelligent encoder. • • Verify motor selection. Verify motor encoder wiring. Damage to feedback device. Call your Rockwell Automation sales representative to return motor for repair. Dedicated overtravel input is inactive. • • • Partial loss of feedback signals. Check all wiring at motor feedback (MF) connector. Improperly sized drive or motor. Verify sizing of system. Mechanical system out of specifications. • • • • The motor feedback wiring is open, shorted, or missing. Position error limit was exceeded. • F 55 Excessive Velocity Error Verify voltage level of the incoming AC power. Check AC power source for glitches or line drop. Install an uninterruptible power supply (UPS) on your AC input. Check wiring. Verify motion profile. Verify axis configuration in software. Increase the feed forward gain. Increase following error limit or time. Check position loop tuning. Verify mechanical integrity of system within specification limits. Check motor power wiring. Partial loss of feedback signals. Check all wiring at motor feedback (MF) connector. Improperly sized drive or motor. • • • Increase velocity error limit or time. Check velocity loop tuning. Verify sizing of system. • • • Increase velocity error limit or time. Check velocity loop tuning. Verify mechanical integrity of system within specification limits. Check motor power wiring. Reduce acceleration. Velocity Error value of the velocity control loop has exceeded the configured value for Velocity Error Tolerance. Mechanical system out of specifications. • • Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 113 Chapter 7 Troubleshoot the Kinetix 350 Drive Table 41 - F xx Fault Codes (continued) Four-digit Display F 56 RSLogix 5000 Fault Message Problem or Symptom Motor torque has exceeded a userprogrammable setting. Overtorque Limit Potential Cause Possible Resolution • • • • Overly aggressive motion profile. Mechanical binding. Mechanical system out of specifications. F 57 F 61 Motor torque has fallen below a userprogrammable setting. Undertorque Limit The hardware enable input was deactivated while the drive was enabled. This is applicable only when drive enable input is used. Drive Enable Input • • • Improperly configured limit. Improperly configured motion. Improperly drive/motor sizing. • • Verify mechanical integrity of system within specification limits. • • • Controller Initiated Exception Verify motion profile. Verify Overtorque settings are appropriate. Verify sizing of system. Mechanical system out of specifications. Verify mechanical integrity of system within specification limits. An attempt was made to enable the axis through software while the Drive Enable hardware input was inactive. • • The Drive Enable input transitioned from active to inactive while the axis was enabled. Verify that Drive Enable hardware input is active whenever the drive is enabled through software. • F 62 Verify motion profile. Verify Overtorque settings are appropriate. Verify sizing of system. Verify torque offset Check wiring of drive enable input. Check 24V source. Move axis out of soft overtravel range. Clear soft overtravel fault. Check soft overtravel configuration. Consult controller documentation. The controller has requested the drive to generate an exception. User configured software overtravel. • • • Problem or Symptom Potential Cause Possible Resolution Wrong motor connected to drive. Connect appropriate motor to drive. Weak battery or poor battery connection. • • Table 42 - Fc xx Fault Codes Four-digit Display RSLogix 5000 Fault Message Fc 02 Motor Voltage Mismatch Motor voltage incompatible with drive voltage. Motor Encoder Battery Loss (applies to Bulletin TLY motors with B feedback) The battery voltage on a battery-backed motor encoder is low enough such that a power loss has caused the absolute position to no longer be available. Fc 06 Motor Encoder Battery Low (applies to Bulletin TLY motors with B feedback) The battery voltage on a battery-backed motor encoder is low enough such that a power loss will cause the absolute position to be lost. Fc 14 Excessive Current Feedback Offset Current in one or more phases has been lost or remains below a preset level. Replace the drive. Fc 26 Runtime Drive Error The drive firmware encountered an unrecoverable runtime error. • • Fc 05 114 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Replace battery. Check battery connection. Cycle control power. Replace drive. Troubleshoot the Kinetix 350 Drive Chapter 7 Table 43 - Ic xx Fault Codes Four-digit Display RSLogix 5000 Fault Message Problem or Symptom Potential Cause Possible Resolution Ic 01 Boot Block Check Sum Fault The motor data stored in a smart encoder has a checksum error. Faulty intelligent encoder. • • Cycle power or reset the drive. Replace motor if faulting continues. Data within a motor data blob is out of range. Faulty intelligent encoder or incorrect motor file. • • Cycle power or reset the drive. Check validity of the motion database. Replace motor if faulting continues. Ic 02 Motor Data Range Error • Ic 03 Ic 06 Motor Feedback Communication Startup Motor Absolute Startup Speed Communication with a smart encoder could not be established on the motor feedback port. The motor absolute encoder was not able to accurately determine the position after powerup due to motor speed greater than 100 rpm. Incorrect motor selected or connected. Check motor selection. Faulty wiring. Check motor encoder wiring. Mechanical movement of machine causing excessive rotation of motor during powerup. Allow machine motion to stop before powerup. Status messages of the format Lxxx indicate an unrecoverable error while starting the drive. Reload firmware and restart the drive, if status message repeats contact Rockwell Automation technical support to return drive for repair. Table 44 - Lxxx Fault Codes Four-digit Display Message Cause L001 Identity block corrupted L002 Firmware file load failed L004 Firmware not programmed (drive is new) L008 DSP load operation failed Status messages of the format Pxxx indicate an unrecoverable error during the Power on Self Test (POST). Contact Rockwell Automation technical support to return drive for repair. Table 45 - Pxxx Fault Codes Four-digit Display Message Cause P001 SDRAM test failed P002 FPGA load operation failed P004 DPRAM Test failed P005 DSP I/F to DPram - no DSP response P006 I/F to DPram failed P007 Firmware file md5 test failure Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 115 Chapter 7 Troubleshoot the Kinetix 350 Drive Table 46 - nF xx Fault Codes Four-digit Display RSLogix 5000 Fault Message Problem or Symptom Potential Cause Possible Resolution • Excessive network traffic. nF 01 Control Update Fault • • Several consecutive updates from the controller have been lost. • Noisy environment. • • • nF 02 Processor Watchdog Fault The watchdog circuit monitoring processor operation detected a problem. • • The drive has an internal hardware problem. • nF 03 • Faulty memory component. • • 116 Segregate signal wiring from power wiring. Use shielded cables. Add snubbers to power devices. Recycle control power or reset the drive. Replace control module if problem persists. Recycle control power or reset the drive. Replace drive. Hardware Fault Nonvolatile write or write to memory failed. nF 04 Remove unnecessary network devices from the motion network. Change the network topology so that fewer devices share common paths. Use faster/higher performance network equipment. Data Format Error A data format error was discovered in the controller-to-drive message. Faulty memory component. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 • Recycle control power or reset the drive. Replace drive if problem persists. Recycle control power or reset the drive. Replace control module if problem persists. Troubleshoot the Kinetix 350 Drive Chapter 7 Status Indicators Table 47 - Drive Status Indicator Status Description Off No power. Apply power. Alternating green/red Self-test (power-up diagnostics). Wait for steady green. Flashing green Standby (device not configured). Wait for steady green. Steady green Normal operation, no faults. Flashing red Minor fault (recoverable). Refer to four-digit fault message. Steady red Major fault (non-recoverable). Refer to four-digit fault message. Table 48 - Axis Status Indicator Status Description Off Off Flash red/green Self test Off Initialization - bus not up Flashing green Initialization - bus up Off Shutdown - bus not up Flashing amber (1) Shutdown - bus up Off Pre-charge - bus not up Flashing amber (1) Start inhibit Flashing green (1) (2) Stopped Stopping Solid green (1) (2) Starting Running Testing Flashing red Solid red Aborting Major faulted Aborting Major faulted (1) The axis and the drive define minor fault conditions. While a minor fault does not affect the drive status indicator, it does affect the axis status indicator. When a minor fault condition is detected, a normally solid green status indicator indication changes to alternating red-green-red-green, a normally flashing green status indicator indication changes to alternating red-off-green-off, and a normally flashing amber indications changes to red-off-amber-off. (2) The drive also defines alarm conditions. When an alarm condition is detected, a normally solid green status indicator indication changes to alternating amber-green-amber green while a normally flashing green status indicator indication changes to alternating amber-off-green-off. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 117 Chapter 7 Troubleshoot the Kinetix 350 Drive Table 49 - Network Status Indicators Status Description Off No power or no IP address defined. Alternating green/red Self-test mode (power-up diagnostics). Flashing green Standby (device not configured, or connection not established. Steady green Normal operation. Device has at least one established connection. Flashing red Recoverable minor fault or connection timeout. Steady red Non-recoverable major fault or duplicate IP address. IMPORTANT Under some fault conditions, two reset commands may be required to clear drive. Table 50 - Port 1 Ethernet Communication Status Indicators 118 Status Description Off No link partner present. Flashing green Link partner present, communication occurring. Steady green Link partner present, no communication occurring. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Troubleshoot the Kinetix 350 Drive Chapter 7 These events do not always result in a fault code, but may require troubleshooting to improve performance. General System Behavior Table 51 - General System Behavior Condition Axis or system is unstable. Potential Cause Possible Resolution The position feedback device is incorrect or open. Check wiring. Unintentionally in Torque mode. Check to see what primary operation mode was programmed. Motor tuning limits are set too high. Run Tune in RSLogix 5000 software. Position loop gain or position controller accel/decel rate is improperly set. Run Tune in RSLogix 5000 software. Improper grounding or shielding techniques are causing noise to be transmitted into the position feedback or velocity command lines, causing erratic axis movement. Check wiring and ground. setups. Motor Select limit is incorrectly set (servo motor is not matched to axis module). •• Check Run Tune in RSLogix 5000 software. You cannot obtain the motor acceleration/deceleration that you want. Motor does not respond to a velocity command. Presence of noise on command or motor feedback signal wires. Mechanical resonance. Notch filter or output filter may be required (refer to Axis Properties dialog box, Output tab in RSLogix 5000 software). Torque Limit limits are set too low. Verify that current limits are set properly. Incorrect motor selected in configuration. Select the correct motor and run Tune in RSLogix 5000 software again. The system inertia is excessive. • Check motor size versus application need. • Review servo system sizing. The system friction torque is excessive. Check motor size versus application need. Available current is insufficient to supply the correct accel/decel rate. • Check motor size versus application need. • Review servo system sizing. Acceleration limit is incorrect. Verify limit settings and correct them, as necessary. Velocity Limit limits are incorrect. Verify limit settings and correct them, as necessary. The axis cannot be enabled for 1.5 seconds after disabling. Disable the axis, wait for 1.5 seconds, and enable the axis. Enable signal has not been applied or the enable wiring is incorrect. • Check the controller. • Check the wiring. The motor wiring is open. Check the wiring. The motor thermal switch has tripped. • Check for a fault. • Check the wiring. The motor has malfunctioned. Repair or replace the motor. The coupling between motor and machine has broken (for example, the motor moves, but the load/machine does not). Check and correct the mechanics. Primary operation mode is set incorrectly. Check and properly set the limit. Velocity or current limits are set incorrectly. Check and properly set the limits. Recommended grounding per installation instructions have not been followed. • Verify grounding. • Route wire away from noise sources. • Refer to System Design for Control of Electrical Noise, publication GMC-RM001. Line frequency may be present. • Verify grounding. • Route wire away from noise sources. Variable frequency may be velocity feedback ripple or a disturbance caused by gear teeth or ballscrew balls, and so forth. The frequency may be a multiple of the motor power transmission components or ballscrew speeds resulting in velocity disturbance. • Decouple the motor for verification. • Check and improve mechanical performance, for example, the gearbox or ballscrew mechanism. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 119 Chapter 7 Troubleshoot the Kinetix 350 Drive Table 51 - General System Behavior Condition No rotation Motor overheating Abnormal noise Erratic operation - Motor locks into position, runs without control or with reduced torque. 120 Potential Cause Possible Resolution The motor connections are loose or open. Check motor wiring and connections. Foreign matter is lodged in the motor. Remove foreign matter. The motor load is excessive. Verify the servo system sizing. The bearings are worn. Return the motor for repair. The motor brake is engaged (if supplied). • Check brake wiring and function. • Return the motor for repair. The motor is not connect to the load. Check coupling. The duty cycle is excessive. Change the command profile to reduce accel/decel or increase time. The rotor is partially demagnetized causing excessive motor current. Return the motor for repair. Motor tuning limits are set too high. Run Tune in RSLogix 5000 software. Loose parts are present in the motor. • Remove the loose parts. • Return motor for repair. • Replace motor. Through bolts or coupling is loose. Tighten bolts. The bearings are worn. Return motor for repair. Mechanical resonance. Notch filter may be required (refer to Axis Properties dialog box, Output tab in RSLogix 5000 software). Motor power phases U and V, U and W, or V and W reversed. Check and correct motor power wiring. Sine, Cosine or Rotor leads are reversed in the feedback cable connector. Check and correct motor feedback wiring. Sine, Cosine, Rotor lead sets of resolver feedback are reversed. Check and correct motor feedback wiring. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Troubleshoot the Kinetix 350 Drive Logix Controller and Drive Behavior Chapter 7 By using RSLogix 5000 software, you can configure how the Bulletin 2097 drives respond when a drive fault/exception occurs. TIP The Ixx faults are always generated after powerup, but before the drive is enabled, so the stopping behavior does not apply. Kinetix 350 Drive Exception Behavior For Kinetix 350 drives, you can configure exception behavior in RSLogix 5000 software from the Axis Properties dialog box, Actions category. Table 52 - Kinetix 350 Drive Exception Action Definitions Exception Action Definition Ignore The controller completely ignores the exception condition. For some exceptions that are fundamental to the operation of the planner, Ignore will not be an available option. Alarm The controller sets the associated bit in the Motion Alarm Status word but does not otherwise affect axis behavior. Like Ignore, if the exception is so fundamental to the drive, Alarm will not be an available option. When an exception action is set to Alarm, the Alarm will go away by itself when the exceptional condition has cleared. Fault Status Only Fault Status Only instructs the controller to set the associated bit in the Motion Fault Status word, but does not otherwise affect axis behavior. However, an explicit Fault Reset is required to clear the fault once the exceptional condition has cleared. If the exception is so fundamental to the drive, Fault Status Only will not be an available option. Stop Planner The controller sets the associated bit in the Motion Fault Status word and instructs the Motion Planner to perform a controlled stop of all planned motion at the configured maximum deceleration rate. An explicit Fault Reset is required to clear the fault once the exceptional condition has cleared. If the exception is so fundamental to the drive, Stop Planner will not be an available option. Stop Drive When the exception occurs, the associated bit in the Fault Status word is set and the axis will come to a stop by using the stopping action defined by the drive for the particular exception that occurred. There is no controller based configuration to specify what the stopping action is, the stopping action is device dependent. Shutdown When the exception occurs, the drive brings the motor to a stop by using the stopping action defined by the drive (as in Stop Drive) and the power module is disabled. Optionally, if the Shutdown Action attribute is configured for Drop DC Bus, the contactor will open. An explicit Shutdown Reset is required to restore the drive to operation. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 121 Chapter 7 Troubleshoot the Kinetix 350 Drive Only selected drives faults can be configured. In the Drive Behavior, F xx Fault Codes tables, the controlling attribute is given for programmable fault actions. Figure 49 - RSLogix 5000 Axis Properties - Actions Category Table 53 - Drive Behavior, F xx Fault Codes Four-digit Display Exception Description Best Stopping Method (major fault only) F 02 Motor Commutation Permanent magnet motor commutation problem detected. Example would be an illegal state 111 or 000 for a UVW commutation device. This exception is supported only for TTL motors with Hall sensors. Disable/Coast F 03 Motor Overspeed Motor speed has exceeded its maximum limit given by the Motor Overspeed Factory Limit attribute associated with the motor type. This exception triggers when either the electrical frequency exceeds 500 Hz or the motor is command to go 125% of its max rated speed. Disable/Coast F 05 Motor Overtemperature Motor temperature has exceeded its factory set temperature limit given by Motor Overtemperature Factory Limit, or the integral motor thermal switch has tripped. Disable/Coast F 07 Motor Thermal Overload Motor thermal model has exceeded its factory set thermal capacity limit given by Motor Thermal Overload Factory Limit. This limit is 108 °C (226 °F) for the Kinetix 350 drive. Decel/Disable F 10 Inverter Overcurrent Inverter current has exceeded the factory set peak or instantaneous current limit. This limit is set to 450% of the rated drive current for a single phase. Disable/Coast F 11 Inverter Overtemperature Inverter temperature has exceeded its factory set temperature limit given by Inverter Overtemperature Factory Limit. Detected when an internal temperature sensor senses 108 °C (226 °F). Disable/Coast F 13 Inverter Thermal Overload Inverter thermal model has exceeded its factory set thermal capacity limit given by Inverter Thermal Overload Factory Limit. This threshold is set to 108 °C (226 °F). Disable/Coast F 33 Bus Undervoltage DC Bus voltage level is below the factory set limit given by Bus Undervoltage Factory Limit. This limit is set at 75% of the nominal voltage as determined on powerup. Decel/Disable F 35 Bus Overvoltage DC Bus voltage level is above the factory set limit given by Bus Overvoltage Factory Limit. For 240V drives the limit is 420V. For 480V drives, the limit is 840V. Disable/Coast 122 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Troubleshoot the Kinetix 350 Drive Chapter 7 Table 53 - Drive Behavior, F xx Fault Codes (continued) Exception Description Best Stopping Method (major fault only) Feedback Signal Loss One or more A/B channel signals from a feedback device are open, shorted, missing, or severely attenuated. Specifically, the detected voltage levels of the signals are below the Feedback Signal Loss Factory Limit. The offending feedback channel is encoded in the associated Fault/Alarm Sub Code. Disable/Coast F 45 Feedback Data Loss The number of consecutive missed or corrupted serial data packets over the serial data channel from a feedback device has exceeded the Feedback Data Loss Factory Limit. The offending feedback channel is encoded in the associated Fault/Alarm Sub Code. The threshold is set at four misses. Disable/Coast F 47 Feedback Device Failure The feedback device has detected an internal error. Stegmann encoders return an error code and Tamagawa encoders have an error flag. Disable/Coast F 50 Hardware Overtravel Positive Axis moved beyond the physical travel limits in the positive direction and activated the Positive Overtravel limit switch. Decel/Disable F 51 Hardware Overtravel Negative Axis moved beyond the physical travel limits in the negative direction and activated the Negative Overtravel limit switch. Decel/Disable F 54 (1) Excessive Position Error The Position Error value of the position control loop has exceeded the configured value for Position Error Tolerance. Decel/Disable F 55 (1) Excessive Velocity Error The Velocity Error value of the velocity control loop has exceeded the configured value for Velocity Error Tolerance. Decel/Disable F 56 Overtorque Limit Motor torque has risen above user defined maximum torque level given by Overtorque Limit. Decel/Disable F 57 Undertorque Limit Motor torque has dropped below user defined minimum torque level given by Undertorque Limit. Decel/Disable F 61 Enable Input Deactivated Enable has been deactivated while the axis is in Running state. Decel/Disable F 62 Controller Initiated Exception Exception generated specifically by controller. Disable/Coast Four-digit Display F 43 (1) (1) When a TTL encoder loses its A/B signals it is not detected directly. Instead a secondary fault to detect the condition, typically excessive position or velocity error. In this case the motor will coast to a stop, but will still be enabled in RSLogix software. IMPORTANT The fault detection ability of TTL encoders is not as advanced as with Stegmann hiperface or Tamagawa 17-bit serial encoders. When a TTL encoder loses its A/ B signals, the Kinetix 350 drive is unable to detect this directly. Instead it relies on a secondary fault to detect the condition, typically excessive position or velocity error. There are some cases, particularly in Torque mode where the fault isn't detected at all. In this case the motor will coast to a stop, but will still be enabled in RSLogix software. Table 54 - Drive Behavior, Fcxx Custom Fault Codes Four-digit Display Exception Description Best Stopping Method (Major Fault Only) Fc02 Motor Voltage Mismatch The motor voltage is incompatible with the applied drive voltage. Disable/Coast Fc05 Feedback Battery Loss The battery voltage on a battery-backed motor encoder is low enough such that absolute position is not longer available. This occurs when the battery is too low and encoder main power has been removed. Decel/Disable Fc06 Feedback Battery Low The battery voltage on a battery-backed motor encoder is below a caution level. This occurs when the battery is too low, but main power has not yet been removed. Decel/Disable Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 123 Chapter 7 Troubleshoot the Kinetix 350 Drive Table 54 - Drive Behavior, Fcxx Custom Fault Codes Four-digit Display Exception Description Best Stopping Method (Major Fault Only) Fc14 Excessive Current Feedback Offset Current in one or more phases has been lost or remains below a preset level. Disable/Coast Fc26 Runtime Error Runtime Assertions detected. Disable/Coast Fc63 Product Specific Product Specific (exotic) exceptions by Sub Code. Disable/Coast A node fault is a fault that impacts the whole drive. Table 55 - Drive Behavior, nFxx Node Fault Codes Four-digit Display Name Description Best Stopping Method nF01 Control Connection Update Fault The Control Connection Update Fault code is used to indicate that updates from the controller over the controller to drive connection have been excessively late as determined by the Controller Update Delay High Limit attribute value. Disable/Coast nF02 Processor Watchdog Fault The Processor Watchdog Fault code indicates that the processor associated with the device node has experienced an excessive overload condition that has tripped the associated processor watchdog mechanism. Disable/Coast nF03 Hardware Fault The Hardware Fault code indicates that the critical support hardware such as the FPGA or ASIC associated with the device node has experienced a fault condition. This will occur when the EPM module has been removed. Disable/Coast nF04 Data Format Error This fault code indicates that an error has occurred in the data format between the controller and the device, such as a Format Revision mismatch. Disable/Coast nF06 Control Connection Loss Fault The Control Connection Loss fault code indicates that the Motion controller to drive connection from the controller has timed out. Disable/Coast 124 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Troubleshoot the Kinetix 350 Drive Web Server Interface Chapter 7 The Kinetix 350 drive supports a basic web interface for common status reporting and network configuration attributes. No attributes are configurable from this page. To access the page open a web browsers program and enter the IP address of the drive. Figure 50 - Main Page Figure 51 - Fault Page Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 125 Chapter 7 Troubleshoot the Kinetix 350 Drive Notes: 126 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Appendix A Specifications and Dimensions Introduction This appendix provides product specifications and mounting dimensions for your Kinetix 350 drive system components. Topic Page Introduction 127 Kinetix 350 Drive Power Specifications 128 Circuit Breaker/Fuse Specifications 131 Power Dissipation Specifications 133 General Specifications 133 AC Line Filter Specifications 135 Shunt Resistor Specifications 136 Product Dimensions 137 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 127 Appendix A Specifications and Dimensions This section contains power specifications for your Kinetix 350 drive system components. Kinetix 350 Drive Power Specifications The 2097-V31PRx-LM drives with 120V input are capable of driving 240V motors at full speed. Table 56 - Kinetix 350 Drive (single-phase) Power Specifications Attribute 2097-V31PR0-LM 2097-V31PR2-LM AC input voltage 70…132V rms single-phase (120V nom) 80…264V rms single-phase (240V nom) AC input frequency 48…62 Hz 2097-V32PR0-LM 2097-V32PR2-LM 2097-V32PR4-LM 80…264V rms single-phase (240V nom) Main AC input current (1) Nom (rms) 120V input (voltage doubler) Max inrush (0-pk) 120V input 9.70 A 1.15 A 15.0 A 1.15 A Nom (rms) 120/240V input Max inrush (0-pk) 240V input 5.0 A 1.1 A 8.6 A 1.1 A 5.0 A 136 A 8.6 A 2.3 A 15.0 A 2.3 A No Yes Yes Yes Current loop update rate 125 μs Command update rate Velocity loop Position loop 500 μs 500 μs Integrated AC line filter No Control power back-up input voltage 20…26V DC Control power back-up input current Nom Max inrush (0-pk) 500 mA 30 A Continuous output current (rms) 2.0 A 4.0 A 2.0 A 4.0 A 8.0 A Continuous output current (0-pk) 2.8 A 5.7 A 2.8 A 5.7 A 11.3 A Peak output current (rms) (2) 6.0 A 12.0 A 6.0 A 12.0 A 24.0 A Peak output current (0-pk) 8.5 A 17.0 A 8.5 A 17.0 A 39.9 A @ 240V nom or 120V (Voltage-doubler mode) 0.40 kW (4) 0.80 kW (4) 0.40 kW 0.80 kW 1.70 kW Shunt On (5) 390V DC Shunt Off (5) 375V DC Overvoltage 430V DC Short circuit current rating 100,000 A (rms) symmetrical Continuous power output (3) (1) (2) (3) (4) (5) 128 Kinetix 350 drive modules are limited to 1 AC mains power cycling per every 2 minutes. Peak RMS current allowed for up to 2 seconds with a 50% duty cycle. Nominal continuous power output (kW) applies to 240V AC drives. Value is approximately one-half of this kW rating when using 120V AC. The 120V voltage-doubler mode applies to only the 2097-V31PRx-LM drives. The drive has an internal shunt transistor. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Specifications and Dimensions Appendix A Table 57 - Kinetix 350 Drive (single-phase and three-phase) Power Specifications Attribute 2097-V33PR1-LM AC input voltage 80…132V rms single-phase (120V nom) 80…264V rms single-phase (240V nom) 80…264V rms three-phase (240V nom) AC input frequency 48…62 Hz Main AC input current (1) Nom (rms) 120V input Max inrush (0-pk) 120V input 5.0 A 68.0 A Nom (rms) 240V input Max inrush (0-pk) 240V input 3.0A 136 A Current loop update rate 125 μs Command update rate Velocity loop Position loop 500 μs 500 μs Integrated AC line filter No Control power back-up input voltage 20…26V DC Control power back-up input current Nom Max inrush (0-pk) 500 mA 30 A Continuous output current (rms) 2.0 A 2097-V33PR3-LM 2097-V33PR5-LM 2097-V33PR6-LM 8.6 A 1.15 A 15.0 A 1.15 A 24.0 A 5.65 A 5.0A 2.3 A 8.7A 2.3 A 13.9 A 11.3 A No No No 4.0 A 8.0 A 12.0 A Continuous output current (0-pk) 2.8 A 5.7 A 11.3 A 17.0 A Peak output current (rms) (2) 6A 12 A 24 A 36 A Peak output current (0-pk) 8.5 A 17.0 A 33.9 A 50.9 A Continuous power output (3) @ 240V nom 0.50 kW 1.00 kW 2.00 kW 3.00 kW Shunt On (4) 390 V DC Shunt Off (4) 375V DC Overvoltage 430V DC Short circuit current rating 100,000 A (rms) symmetrical (1) (2) (3) (4) Kinetix 350 drive modules are limited to 1 AC mains power cycling per every 2 minutes. Peak RMS current allowed for up to 2 seconds with a 50% duty cycle. Nominal continuous power output (kW) applies to 240V AC drives. Value is approximately one-half of this kW rating when using 120V AC. The drive has an internal shunt transistor. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 129 Appendix A Specifications and Dimensions Table 58 - Kinetix 350 Drive (three-phase) Power Specifications Attribute 2097-V34PR3-LM 2097-V34PR5-LM AC input voltage 320…528V rms three-phase (480V nom) AC input frequency 48…62 Hz 2097-V34PR6-LM Main AC input current (1) Nom (rms) Max inrush (0-pk) 2.7A 4.5 A 5.5 A 4.5 A 7.9 A 22.6 A No No Current loop update rate 125 μs Command update rate Velocity loop Position loop 500 μs 500 μs Integrated AC line filter No Control power back-up input voltage 20…26V DC Control power back-up input current Nom Max inrush (0-pk) 500 mA 30 A Continuous output current (rms) 2.0 A 4.0 A 6.0 A Continuous output current (0-pk) 2.8 A 5.7 A 8.5 A Peak output current (rms) (2) 6A 12 A 18 A Peak output current (0-pk) 8.5 A 17.0 A 25.5 A Continuous power output @ 480V nom 1.00 kW 2.00 kW 3.00 kW Shunt On (3) 780V DC Shunt Off (3) 750V DC Overvoltage 850V DC Short circuit current rating 100,000 A (rms) symmetrical (1) Kinetix 350 drive modules are limited to 1 AC mains power cycling per every 2 minutes. (2) Peak RMS current allowed for up to 2 seconds with a 50% duty cycle. (3) The drive has an internal shunt transistor. 130 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Specifications and Dimensions Circuit Breaker/Fuse Specifications Appendix A While circuit breakers offer some convenience, there are limitations for their use. Circuit breakers do not handle high current inrush as well as fuses. Make sure the selected components are properly coordinated and meet acceptable codes including any requirements for branch circuit protection. Evaluation of the short-circuit available current is critical and must be kept below the short-circuit current rating of the circuit breaker. Use class CC or T fast-acting current-limiting type fuses, 200,000 AIC, preferred. Use Bussmann KTK-R, JJN, JJS or equivalent. Thermal-magnetic type breakers preferred. The following fuse examples and Allen-Bradley circuit breakers are recommended for use with Kinetix 350 drives. Main VAC Cat. No. 2097-V31PR0-LM 2097-V31PR2-LM 2097-V32PR0-LM 2097-V32PR2-LM 2097-V32PR4-LM 2097-V33PR1-LM 2097-V33PR3-LM 2097-V33PR5-LM 2097-V33PR6-LM Drive Voltage 2097-V34PR6-LM Bussmann Fuse Disconnect (2) Magnetic Contactor (3) 120V KTK-R-20 (20A) 1492-SP1D200 140M-F8E-C20 240V KTK-R-10 (10A) 1492-SP1D100 140M-F8E-C10 120V KTK-R-30 (30A) 1492-SP1D300 140M-F8E-C32 240V KTK-R-20 (20A) 1492-SP1D200 140M-F8E-C20 240V KTK-R-20 (20A) 1492-SP3D200 140M-F8E-C20 240V KTK-R-30 (30A) 1492-SP3D320 140M-F8E-C32 120V KTK-R-20 (20A) 1492-SP1D200 140M-F8E-C20 240V KTK-R-15 (15A) 1492-SP3D150 140M-F8E-C16 120V KTK-R-20 (20A) 1492-SP1D200 140M-F8E-C20 240V KTK-R-15 (15A) 1492-SP3D150 140M-F8E-C16 120V KTK-R-30 (30A) 1492-SP1D300 140M-F8E-C32 240V KTK-R-20 (20A) 1492-SP3D200 140M-F8E-C20 120V N/A N/A N/A 240V KTK-R-30 (30A) 1492-SP3D300 140M-F8E-C32 KTK-R-10 (10A) 1492-SP3D100 140M-F8E-C10 KTK-R-10 (10A) 1492-SP3D100 140M-F8E-C10 KTK-R-20 (20A) 1492-SP3D200 140M-F8E-C20 2097-V34PR3-LM 2097-V34PR5-LM Allen-Bradley Circuit Breaker (1) 480V (1) When using Bulletin 1492 circuit protection devices, the maximum short circuit current available from the source is limited to 5000 A. (2) Use fully-rated short-circuit protection circuit breaker for device branch circuit protection only when there is an upstream fully-rated breaker. (3) Fully-rated breaker for overload current and short circuit rating. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 131 Appendix A Specifications and Dimensions Contactor Ratings Table 59 - Kinetix 350 Drives (120/240V) Cat. No. 2097-V31PR0-LM 2097-V31PR2-LM Drive Voltage AC Coil Contactor DC Coil Contactor 120V 100-C23x10 100-C23Zx10 240V 100-C12x10 100-C12Zx10 120V 100-C30x10 100-C30Zx10 240V 100-C23x10 100-C23Zx10 Table 60 - Kinetix 350 Drives (240V) Cat. No. Drive Voltage AC Coil Contactor DC Coil Contactor 2097-V32PR0-LM 240V 100-C23x10 100-C23Zx10 2097-V32PR2-LM 240V 100-C23x10 100-C23Zx10 2097-V32PR4-LM 240V 100-C30x10 100-C30Zx10 120V 100-C23x10 100-C23Zx10 240V 100-C16x10 100-C16Zx10 120V 100-C23x10 100-C23Zx10 240V 100-C16x10 100-C16Zx10 120V 100-C30x10 100-C30Zx10 240V 100-C23x10 100-C23Zx10 120V N/A N/A 240V 100-C30x10 100-C30Zx10 AC Coil Contactor DC Coil Contactor 100-C12x10 100-C12Zx10 100-C12x10 100-C12Zx10 100-C23x10 100-C23Zx10 2097-V33PR1-LM 2097-V33PR3-LM 2097-V33PR5-LM 2097-V33PR6-LM Table 61 - Kinetix 350 Drives (480V) Cat. No. Drive Voltage 2097-V34PR3-LM 2097-V34PR5-LM 480V 2097-V34PR6-LM Transformer Specifications for Input Power 132 Attribute Value (460V system) Input volt-amperes 750VA Input voltage 480V AC Output voltage 120…240V AC Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Specifications and Dimensions Power Dissipation Specifications General Specifications Appendix A This table shows the maximum power dissipation of each drive. Use this table to size an enclosure and calculate required ventilation for your Kinetix 350 drive system. Cat. No. Power Dissipation, W 2097-V31PR0-LM 28 2097-V31PR2-LM 39 2097-V32PR0-LM 28 2097-V32PR2-LM 39 2097-V32PR4-LM 67 2097-V33PR1-LM 28 2097-V33PR3-LM 39 2097-V33PR5-LM 67 2097-V33PR6-LM 117 2097-V34PR3-LM 39 2097-V34PR5-LM 58 2097-V34PR6-LM 99 This section contains general specifications for your Kinetix 350 drive system components. Environmental Specifications Attribute Operating Range Storage Range (nonoperating) Ambient temperature 0…40 °C (32…104 °F) -10…70 °C (14…158°F) Relative humidity 5…95% noncondensing 5…95% noncondensing Altitude De-rate by 1% per 300 m (1000 ft) above 1500 m (5000 ft) 3000 m (9843 ft) during transport Vibration 5…2000 Hz @ 2.5 g peak, 0.015 mm (0.0006 in.) max displacement Shock 15 g, 11 ms half-sine pulse (3 pulses in each direction of 3 mutually perpendicular directions) Maximum Feedback Cable Lengths Although Bulletin 2090 motor feedback cables are available in standard lengths up to 90 m (295.3 ft), the maximum feedback cable length for connecting motors or actuators to Kinetix 350 drives is 20 m (65.6 ft). IMPORTANT System performance was tested at these cable length specifications These limitations are also a CE requirement. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 133 Appendix A Specifications and Dimensions Weight Specifications Kinetix 350 Drive Cat. No. Value, approx. kg (lb) 2097-V31PR0-LM 1.3 (2.86) 2097-V31PR2-LM 1.5 (3.31) 2097-V32PR0-LM 1.4 (3.09) 2097-V32PR2-LM 1.7 (3.75) 2097-V32PR4-LM 2.2 (4.85) 2097-V33PR1-LM 1.3 (2.86) 2097-V33PR3-LM 1.5 (3.31) 2097-V33PR5-LM 2.0 (4.41) 2097-V33PR6-LM 1.9 (4.19) 2097-V34PR3-LM 1.5 (3.31) 2097-V34PR5-LM 2.0 (4.41) 2097-V34PR6-LM 1.8 (3.97) Certifications Certification (1) (when product is marked) Standards UL Listed to U.S. and Canadian safety standards (UL 508 C File E59272). c-UL-us Solid-state motor overload protection provides dynamic fold-back of motor current when 110% of the motor rating is reached with a peak current limit based on the peak rating of the motor as investigated by UL to comply with UL 508C (UL File E59272, volume 1, section 22). CE European Union 2004/108/EC EMC Directive compliant with EN 61800-3:2004: Adjustable Speed Electrical Power Drive Systems - Part 3; EMC Product Standard including specific test methods. European Union 2006/95/EC Low Voltage Directive compliant with: • EN 61800-5-1:2003 - Safety of Machinery - Electrical Equipment of Machines. • EN 50178:1997 - Electronic Equipment for use in Power Installations. Functional Safety • EN 61800-5-2:2007 - Adjustable speed electrical power drive systems • EN 62061:2005 - Safety of machinery - Functional safety of safety-related electrical, electronic and programmable electronic control systems • EN ISO 13849-1:2008 - Safety of machinery - Safety-related parts of control systems • IEC 61508:Part 1-7:2000 - Functional Safety of Electrical/Electronic/Programmable Electronic Safety-related Systems C-Tick • • • • Radio Communications Act: 1992 Radio Communications (Electromagnetic Compatibility) Standard: 1998 Radio Communications (Compliance Labelling - Incidental Emissions) Notice: 1998 AS/NZS CISPR 11: 2003 (Group 1, Class A) (1) Refer to http://www.ab.com for Declarations of Conformity Certificates. 134 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Specifications and Dimensions Appendix A These tables contain specifications for AC line filters available for Kinetix 350 servo drive systems. AC Line Filter Specifications Table 62 - AC Line Filter Specifications (Bulletin 2090) Attribute Kinetix 350 Cat. No. Drive (1) 2090-XXLF-TC116 2090-UXLF-336 2097-V31PR0-LM 2097-V31PR2-LM 2097-V33PR5-LM Voltage 250V AC 50/60 Hz Phase Single Three-phase Current A @ 50 °C (122 °F) 16 36 Power loss W – – Leakage current mA 87 136 Weight, approx. kg (lb) 0.80 (1.7) 2.7 (5.9) Humidity 90% relative humidity Vibration 10…200 Hz @ 1.8 g vibration Operating temperature -25…100 °C (-13…212 °F) -25…85 °C (-13…185 °F) (1) Kinetix 350 drives (catalog numbers 2097-V32PR0-LM, 2097-V32PR2-LM, and 2097-V32PR4-LM) have integrated AC line filters. Table 63 - AC Line Filter Specifications (Bulletin 2097) Attribute 2097-F1 2097-F4 (1) 2097-F2 2097-F5 (1) 2097-F6 (1) Kinetix 350 Drive (2) Cat. No. 2097-V33PR6-LM 2097-V34PR6-LM 2097-V33PR1-LM 2097-V34PR3-LM Voltage 120/240V AC 50/60 Hz 480V AC 50/60 Hz 120/240V AC 50/60 Hz 480V AC 50/60 Hz 120/240V AC 50/60 Hz Phase Single-phase Three-phase Single or Threephase Three-phase Single or Threephase Current A @ 40 °C (104 °F) 24 10 4.4 6.9 15.0 Power loss W 5.2 2.8 1.2 1.3 4.1 Leakage current mA 9 1 Weight, approx. kg (lb) 0.6 (1.3) Humidity 5…95% noncondensing Vibration 5…2000 Hz @ 2.5 g peak, 0.015 mm (.0006 in.) maximum displacement Operating temperature 0…40 °C (32…104 °F) 2097-V34PR5-LM 2097-V33PR3-LM 2097-V33PR5-LM Single-phase 0.8 (1.8) (1) This filter is rated for multiple voltage/phase line conditions. (2) Kinetix 350 drives (catalog numbers 2097-V32PR0-LM, 2097-V32PR2-LM, and 2097-V32PR4-LM) have integrated AC line filters. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 135 Appendix A Specifications and Dimensions Shunt Resistor Specifications Bulletin 2097 passive shunt resistor wire to the Kinetix 350 drive. Table 64 - Shunt Resistor Power Specifications Attribute 2097-R2 2097-R3 2097-R4 2097-R6 2097-R7 2097-V34PR5-LM 2097-V34PR6-LM 2097-V34PR3-LM Use with Kinetix 350 drive Cat. No. 2097-V32PR4-LM 2097-V33PR5-LM 2097-V33PR6-LM 2097-V31PR0-LM 2097-V31PR2-LM 2097-V32PR0-LM 2097-V32PR2-LM 2097-V33PR1-LM 2097-V33PR3-LM Resistor value 20 30 40 75 150 Peak power kW 7.6 5.1 3.8 7.9 4.0 Peak current A 19.5 13.0 9.8 10.3 5.1 80 150 80 2.96 2.10 1.90 2.02 0.2 (0.4) 0.3 (0.7) 0.2 (0.4) Continuous power W 150 % RD_Application, max (1) 1.97 Weight, approx. kg (lb) 0.3 (0.7) (1) RD_Application is the application duty cycle in percent. For the intermittent regeneration applications use RD_Application = t/T. Where t is the duration when regeneration is needed and T is the time interval between two regenerations. Both t and T must use the same time units such as seconds. 136 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Specifications and Dimensions Appendix A This section contains product dimensions for your Kinetix 350 servo drives. Product Dimensions A 5.0 (0.19) Dimensions are in mm (in.). 7.1 (0.28) 30.8 (1.21) 2097-Vxxxxx-LM Servo Drive 9.7 (0.38) 182 (7.18) 238 (9.37) 190 (7.50) 2097-TB1 I/O Terminal Expansion Block 6.6 (0.26) 2090-K2CK-D15M Low-profile Connector Kit for 61.0 Bulletin 2090 (flying-lead) (2.40) Feedback Cable 11.8 (0.46) Ø 4.57 (0.18) 3x 38.1 (1.5) B Additional clearance below the connector kit is necessary to provide the recommended cable bend radius. Table 65 - Kinetix 350 Dimensions Cat. No. A mm (in.) B mm (in.) Cat. No. A mm (in.) B mm (in.) 2097-V31PR0-LM 185 (7.29) 68.0 (2.68) 2097-V33PR3-LM 185 (7.29) 69.0 (2.70) 2097-V31PR2-LM 185 (7.29) 69.0 (2.70) 2097-V33PR5-LM 185 (7.29) 94.0 (3.72) 2097-V32PR0-LM 230 (9.04) 68.0 (2.68) 2097-V33PR6-LM 230 (9.04) 68.0 (2.68) 2097-V32PR2-LM 230 (9.04) 69.0 (2.70) 2097-V34PR3-LM 185 (7.29) 69.0 (2.70) 2097-V32PR4-LM 230 (9.04) 87.0 (3.42) 2097-V34PR5-LM 185 (7.29) 94.0 (3.72) 2097-V33PR1-LM 185 (7.29) 68.0 (2.68) 2097-V34PR6-LM 230 (9.04) 68.0 (2.68) Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 137 Appendix A Specifications and Dimensions Notes: 138 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Appendix B Interconnect Diagrams Introduction This appendix provides wiring examples and system block diagrams for your Kinetix 350 drive system components. Topic Page Introduction 139 Interconnect Diagram Notes 140 Power Wiring Examples 141 Kinetix 350 Drive/Rotary Motor Wiring Examples 144 Kinetix 350 Drive/Actuator Wiring Examples 146 Motor Brake Currents 149 System Block Diagrams 150 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 139 Appendix B Interconnect Diagrams This appendix provides wiring examples to assist you in wiring the Kinetix 350 system. The notes below apply to the wiring examples on the pages that follow. Interconnect Diagram Notes Note Information 1 For power wiring specifications, refer to Power Wiring Requirements on page 55. 2 For input fuse and circuit breaker sizes, refer to Circuit Breaker/Fuse Specifications on page 131. 3 Place the AC (EMC) line filters as close to the drive as possible and do not route very dirty wires in the wireway. If routing in wireway is unavoidable, use shielded cable with shields grounded to the drive chassis and filter case. For AC line filter specifications, refer to AC Line Filter Specifications on page 135. This filter does not apply to 2097V32PRx-LM drives because they have integrated AC line filters. 4 Terminal block is required to make connections. 5 Contactor coil (M1) needs integrated surge suppressors for AC coil operation. Refer to Contactor Ratings on page 132. 6 Refer to the Motor Brake Currents table on page 149 to size the interposing relay for your application and for a detailed schematic of brake implementation. 7 Drive Enable input must be opened when main power is removed, or a drive fault occurs. A delay of at least 1.0 second must be observed before attempting to enable the drive after main power is restored. 8 Cable shield clamp must be used to meet CE requirements. No external connection to ground is required. 9 For motor cable specifications, refer to the Kinetix Motion Control Selection Guide, publication GMC-SG001. 10 Motor power cables (catalog numbers 2090-XXNPMF-xxSxx and 2090-CPBM6DF-16AAxx) have a drain wire that must be folded back under the cable shield clamp. 11 MPL-Axxx, MPM-Axxx, MPF-Axxx, MPS-Axxx, MPAR-Axxx, MPAI-Axxx, and MPAS-Axxx, encoders use the +5V DC supply. MPL-Bxxx, MPM-Bxxx, MPF-Bxxx, MPS-Bxxx, MPARBxxx, MPAI-Bxxx, and MPAS-Bxxx, encoders use +9V DC. 12 Brake connector pins are labeled plus (+) and minus (-) or F and G respectively. Power connector pins are labeled U, V, W, and GND or A, B, C, and D respectively. 140 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Interconnect Diagrams Appendix B You must supply input power components. The single-phase and three-phase line filters are wired downstream of fusing and the M1 contactor. Power Wiring Examples In this example, the 2097-V31PRx-LM drives are wired to use the voltage doubling circuit. The 120V input voltage provides 240V output to motors. The 2097-V33PRx-LM drives are wired for single-phase 120V operation. Figure 52 - Kinetix 350 Drive (120V single-phase input power) 2097-V31PRx -LM and 2097-V33PRx-LM Kinetix 350 Drives Refer to table on page 140 for note information. Ground Stud Bonded Cabinet Ground Bus * AC Line Filter (Optional) L2/N Single-phase AC Input 120V rms AC, 50/60 Hz 2097-V31PRx-LM 2097-V33PRx-LM PE PE N L2 L1 L1 L2/N L3 Note 3 L1 Notes 1, 2 Fuse Disconnect or Circuit Breakers Input Fusing * M1 * Notes 5, 7 Mains Single-phase AC Input (IPD) Connector Shunt Resistor and DC Bus (BC) Connector B+ B+ BR BB- Shunt Resistor Connections Back-up Power (BP) Connector +24V DC User-supplied +24V DC Motor Power (MP) Connector -24V DC U V W Three-phase Motor Power Connections Note 9 PE Use discrete logic or PLC to control ENABLE to drive. 29 26 EN ACOM I/O (IOD) Connector Cable Shield Clamp Note 8 Note 4 * Indicates User Supplied Component Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 141 Appendix B Interconnect Diagrams In this example, single-phase 240V AC is applied to 2097-V31PRx-LM and 2097-V32PRx-LM drives. IMPORTANT The 2097-V32PRx-LM models have integrated AC line filters and do not require the AC line filter shown in this diagram. Figure 53 - Kinetix 350 Drives (240V single-phase input power) 2097-V31PRx-LM, 2097-V32PRx-LM 2097-V33PRx-LM and Kinetix 350 Drive Refer to table on page 140 for note information. Ground Stud Bonded Cabinet Ground Bus * 2097-V31PRx-LM 2097-V32PRx-LM PE L1 Single-phase AC Input 120/240V rms AC, 50/60 Hz PE AC Line Filter (Optional) N Note 3 L1 L1 L2/N L2 L2/N Notes 1, 2 Fuse Disconnect or Circuit Breakers Input Fusing * M1 * Notes 5, 7 Mains Single-phase AC Input (IPD) Connector Shunt Resistor and DC Bus (BC) Connector Back-up Power (BP) Connector Motor Power (MP) Connector B+ B+ BR BB- Shunt Resistor Connections +24V DC User-supplied +24V DC -24V DC U V W PE Use discrete logic or PLC to control ENABLE to drive. 29 26 EN ACOM Note 9 I/O (IOD) Connector Cable Shield Clamp Note 4 Note 8 * Indicates User Supplied Component 142 Three-phase Motor Power Connections Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Interconnect Diagrams Appendix B In this example, three-phase 240V AC is applied to 2097-V33PR x-LM drives and 480V AC is applied to 2097-V34PRx-LM drives. Figure 54 - Kinetix 350 Drive (240/480V three-phase input power) 2097-V33PRx-LM and 2097-V34PRx-LM Kinetix 350 Drive Refer to table on page 140 for note information. Ground Stud Shunt Resistor and DC Bus (BC) Connector B+ B+ BR BB- Shunt Resistor Connections Bonded Cabinet Ground Bus * PE AC Line Filter (optional) Note 3 L1 Three-phase AC Input 240/480V rms AC, 50/60 Hz L1 L2 Notes 1, 2 L2 L3 Fuse Disconnect or Circuit Breakers Input Fusing * Mains Three-phase Input (IPD) Connector L3 Back-up Power (BP) Connector M1 * Notes 5, 7 +24V DC -24V DC U Use discrete logic or PLC to control ENABLE to drive 29 26 Motor Power (MP) Connector EN ACOM I/O (IOD) Connector V W User-supplied +24V DC Three-phase Motor Power Connections Note 9 PE Note 4 Cable Shield Clamp Note 8 * Indicates User Supplied Component IMPORTANT For the 480V Kinetix 350 drives to meet ISO 13849-1 (PLd) spacing requirements, each phase voltage to ground must be less than or equal to 300V AC rms. This means that the power system must use center grounded wye secondary configuration for 400/480V AC mains. Shunt Resistor Wiring Example Refer to the Shunt Resistor Specifications on page 136, for the Bulletin 2097-Rx shunt resistors available for the Kinetix 350 drives. Refer to the Shunt Resistor Installation Instructions, publication 2097-IN002, for additional installation information. Figure 55 - Shunt Resistor Wiring Example 2097-V3xPRx-LM Kinetix 350 Drive Brake/DC Bus (BC) Connector (1) B+ B+ BR BB- 2097-Rx Shunt Resistor (1) This connector is for the Shunt resistor not the motor brake. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 143 Appendix B Interconnect Diagrams These wiring diagrams apply to Kinetix 350 drives with compatible rotary motors. Kinetix 350 Drive/Rotary Motor Wiring Examples Figure 56 - MP-Series (Bulletin MPL, MPM, MPF, and MPS) Motors 2090-XXNPMF-xxSxx (standard) or 2090-CPBMxDF-xxAFxx (continuous-flex) Motor Power Cable Notes 9, 10 Use 2090-CPWMxDF-xxAFxx cable for continuous flex non-brake applications. 2097-V3xPRx-LM Kinetix 350 Drives 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 MPL-A/Bxxx, MPM-A/Bxxx MPF-A/Bxxx, and MPS-A/Bxxx Servo Motors with High Resolution Feedback Shield Green/Yellow Motor Power (MP) Connector 1 2 BLACK WHT/BLACK 3 4 RED WHT/RED 5 6 9 10 11 13 GREEN WHT/GREEN C/W B/V W Brown A/U U GND V Motor Feedback Motor Feedback (MF) Connector 2090-K2CK-D15M Connector Kit Three-phase Motor Power Black Blue W V U D/ Refer to table on page 140 for note information. Note 12 Thermostat Black G/- BR- 14 White F/+ BR+ 12 Motor Brake I/O (IOD) Connector Note 4 MTR_BRAKE MTR_BRAKE + Cable Shield Clamp Note 6 Note 8 ORANGE WHT/ORANGE DATA+ DATA+5VDC ECOM +9VDC TS+ 5 10 14 6 7 11 BLUE TS- GRAY WHT/GRAY COM 2090-XXNFMF-Sxx (standard) or 2090-CFBMxDF-CDAFxx (continuous-flex) (flying-lead) Feedback Cable Notes 9, 11 MPL-A/B15xx and MPL-A/B2xx MPL-A/B3xx…MPL-A/B45xx Servo Motors with Incremental Feedback 24V DC 24V DC COM User Supplied 24V DC Grounding Technique for Feedback Cable Shield 3 4 Refer to low profile connector illustration (lower left) for proper grounding technique. 44 43 CR1 C B W A U GND V Three-phase Motor Power Motor Feedback Low Profile Connector (2090-K2CK-D15M shown) Thermostat G Clamp Exposed shield secured under clamp. F BRBR+ Motor Brake Clamp Screws (2) Turn clamp over to hold small cables secure. 2090-K2CK-D15M Connector Kit 1 2 BLACK WHT/BLACK 3 4 RED WHT/RED 5 6 9 10 11 13 GREEN WHT/GREEN 14 15 16 17 12 GRAY WHT/GRAY ORANGE WHT/ORANGE BLUE WHT/BLUE YELLOW WHT/YELLOW AM+ AMBM+ BMIM+ IM+5VDC ECOM – TS+ TSS1 S2 S3 COM Refer to low profile connector illustration (lower left) for proper grounding technique. 2090-XXNFMF-Sxx (non-flex) or 2090-CFBMxDF-CDAFxx (continuous-flex) (flying-lead) Feedback Cable Note 9 144 1 2 SIN+ SINCOS+ COS- Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 1 2 3 4 5 10 14 6 11 12 13 8 Interconnect Diagrams Appendix B Figure 57 - Kinetix 350 Drive with TL-Series (TLY-A) Motors 2097-V3xPRx-LM Kinetix 350 Drives 2090-CPBM6DF-16AAxx Motor Power and Brake Cable Notes 9, 10 Use 2090-CPWM6DF-16AAxx cable for non-brake applications. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Motor Power (MP) Connector W V U Green/Yellow 5 Blue 3 2 W Black Brown 1 U GND V Motor Feedback Black 9 BR- White 7 BR+ Motor Brake Note 4 MTR_BRAKE + Cable Shield Clamp 44 43 2090-K2CK-D15M Connector Kit Three-phase Motor Power Motor Feedback (MF) Connector I/O (IOD) MTR_BRAKE Connector Refer to table on page 140 for note information. TLY-Axxxx-H (230V) Servo Motors with Incremental Feedback 9 10 BLACK WHT/BLACK 11 12 RED WHT/RED 3 4 13 14 GREEN WHT/GREEN IM+ IM- 5 10 22 23 GRAY WHT/GRAY +5VDC ECOM 14 6 15 17 19 WHT/BLUE S1 YELLOW WHT/YELLOW S2 S3 SHIELD 12 13 8 24 Note 8 Refer to low-profile connector illustration (lower left) for proper grounding technique. CR1 Note 6 2090-CFBM6DF-CBAAxx (flying-lead) or 2090-CFBM6DD-CCAAxx (with drive-end connector) Feedback Cable Note 9 24V DC 24V DC COM TLY-Axxxx-B (230V) Servo Motors with High-Resolution Feedback User Supplied 24V DC Grounding Technique for Feedback Cable Shield Low Profile Connector (2090-K2CK-D15M shown) 3.6V battery (2090-DA-BAT2) only required for use with TLY-Axxxx-B motors (high-resolution 17-bit encoders). 5 3 2 W 1 U V Exposed shield secured under clamp. Clamp GND 13 14 GREEN WHT/GREEN 22 23 6 GRAY WHT/GRAY 24 Clamp Screws (2) 1 2 AM+ AMBM+ BM- Turn clamp over to hold small cables secure. 9 BR- 7 BR+ Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 ORANGE WHT/ORANGE DATA+ DATA+5VDC ECOM BAT+ BATSHIELD 5 10 14 6 BAT+ BAT- Refer to low-profile connector illustration (lower left) for proper grounding technique. 2090-CFBM6DF-CBAAxx (flying-lead) or 2090-CFBM6DD-CCAAxx (with drive-end connector) Feedback Cable Note 9 145 Appendix B Interconnect Diagrams Kinetix 350 Drive/Actuator Wiring Examples These wiring diagrams apply to Kinetix 350 drives with compatible linear actuators. Figure 58 - Kinetix 350 Drive with MP-Series (Bulletin MPAS-A/B) Linear Stages 2090-XXNPMF-xxSxx (standard) or 2090-CPBM4DF-xxAFxx (continuous-flex) Motor Power Cable Notes 9, 10 Use 2090-CPWM4DF-xxAFxx cable for continuous-flex non-brake applications. 2097-V3xPRx-LM Kinetix 350 Drives 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 MPAS-A/Bxxxxx-VxxSxA Ballscrew Linear Stages with High Resolution Feedback Shield Motor Power (MP) Connector Three-phase Motor Power Green/Yellow D Blue C B W Black Brown A U W V U GND V Motor Feedback Motor Feedback (MF) Connector Thermostat Black G BR- White F BR+ Motor Brake 44 43 I/O (IOD) MTR_BRAKE Connector Note 4 MTR_BRAKE + Cable Shield Clamp Note 8 CR1 Note 6 24V DC 24V DC COM User Supplied 24V DC Grounding Technique for Feedback Cable Shield Low Profile Connector (2090-K2CK-D15M shown) Clamp Exposed shield secured under clamp. Clamp Screws (2) Turn clamp over to hold small cables secure. 146 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Refer to table on page 140 for note information. 2090-K2CK-D15M Connector Kit 1 2 BLACK WHT/BLACK 3 4 RED WHT/RED 5 6 9 10 11 13 GREEN WHT/GREEN 14 12 1 2 SIN+ SINCOS+ COS- 3 4 ORANGE WHT/ORANGE DATA+ DATA+5VDC ECOM +9VDC TS+ 5 10 14 6 7 11 BLUE TS- GRAY WHT/GRAY COM Refer to low profile connector illustration (lower left) for proper grounding technique. 2090-XXNFMF-Sxx (standard) or 2090-CFBM4DF-CDAFxx (continuous-flex) (flying-lead) Feedback Cable Notes 9, 11 Interconnect Diagrams Appendix B Figure 59 - Kinetix 350 Drive with MP-Series (Bulletin MPAR and MPAI) Electric Cylinders 2097-V3xPRx-LM Kinetix 350 Drives 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 MPAR-A/Bxxxxx-xxx and MPAI-A/Bxxx Electric Cylinder with High Resolution Feedback See MP-Series Electric Cylinder Power and Feedback Cables, Table 65 Notes 9, 10 Shield Motor Power (MP) Connector W V U Three-phase Motor Power Green/Yellow D Blue C B W Black Brown A U GND V Motor Feedback Motor Feedback (MF) Connector Thermostat Black G BR- White F BR+ Refer to table on page 140 for note information. 2090-K2CK-D15M Connector Kit 1 2 BLACK WHT/BLACK SIN+ SIN- 1 2 3 4 RED WHT/RED COS+ COS- 3 4 5 6 9 10 11 13 GREEN WHT/GREEN GRAY WHT/GRAY DATA+ DATA+5VDC ECOM ORANGE WHT/ORANGE +9VDC TS+ 5 10 14 6 7 11 BLUE TSCOM 14 12 Refer to low profile connector illustration below for proper grounding technique. Motor Brake I/O (IOD) MTR_BRAKE Connector Note 4 MTR_BRAKE + 44 43 See MP-Series Electric Cylinder Power and Feedback Cables, Table 65 Cable Shield Clamp Notes 9, 11 Note 8 CR1 Note 6 24V DC 24V DC COM User Supplied 24V DC Low Profile Connector (2090-K2CK-D15M shown) Table 65 - MP-Series Electric Cylinder Power and Feedback Cables Clamp Exposed shield secured under clamp. Clamp Screws (2) Turn clamp over to hold small cables secure. MP-Series Electric Cylinder Cat. No. MPAR-A/B1xxx MPAR-A/B2xxx 40 MPAR-A/B3xxx 63 MPAI-A/Bxxx Frame Grounding Technique for Feedback Cable Shield Power Cable Cat. No. Feedback Cable Cat. No. 32 2090-XXNPMF-16Sxx (standard) 2090-CPxM4DF-16AFxx (continuous-flex) 2090-XXNFMF-Sxx (standard) 2090-CFBM4DF-CDAFxx (continuous-flex) 2090-CPxM7DF-16AAxx (standard) 2090-CPxM7DF-16AFxx (continuous-flex) 2090-CFBM7DF-16AAxx (standard) 2090-CFBM7DF-CEAAxx (continuous-flex) 83 110 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 147 Appendix B Interconnect Diagrams Figure 60 - Kinetix 350 Drive with TL-Series (Bulletin TLAR) Electric Cylinders 2097-V3xPRx-LM Kinetix 350 Drives 0 1 2 Motor Power 3 (MP) Connector 4 5 6 Motor Feedback 7 (MF) Connector 8 9 10 11 12 13 14 15 TLAR-Axxxxx-B (230V) Servo Motors with High Resolution Feedback 2090-CPBM6DF-16AAxx Motor Power and Brake Cable Notes 9, 10 Use 2090-CPWM6DF-16AAxx cable for non-brake applications. Three-phase Motor Power Green/Yellow 5 Blue W Black 3 2 Brown 1 U W V U Refer to table on page 140 for note information. 2090-K2CK-D15M Connector Kit GND V Motor Feedback Black 9 BR- White 7 BR+ 13 14 GREEN WHT/GREEN 22 23 6 GRAY WHT/GRAY 24 ORANGE WHT/ORANGE DATA+ DATA+5VDC ECOM BAT+ BATSHIELD Refer to low-profile connector illustration (lower left) for proper grounding technique. Motor Brake I/O (IOD) MTR_BAKE Connector Note 4 MTR_BRAKE + 44 43 Cable Shield Clamp Note 8 CR1 Note 6 24V DC 24V DC COM User Supplied 24V DC Grounding Technique for Feedback Cable Shield Low Profile Connector (2090-K2CK-D15M shown) 3.6V battery (2090-DA-BAT2) required for use with TLAR-Axxxxx-B electric cylinders (high-resolution 17-bit encoders). Exposed shield secured under clamp. Clamp Clamp Screws (2) 148 Turn clamp over to hold small cables secure. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 2090-CFBM6DF-CBAAxx (flying-lead) or 2090-CFBM6DD-CCAAxx (with drive-end connector) Feedback Cable Note 9 5 10 14 6 BAT+ BAT- Interconnect Diagrams Motor Brake Currents Appendix B Use these coil current values to size the interposing relay required for your application. Refer to the interconnect diagram for your Kinetix 350 drive/motor beginning on page 144 for typical motor brake circuitry. Table 66 - Motor Brake Coil Currents Compatible Brake Motors/Actuators (1) Coil Current MPL-x1510, MPL-x1520, MPL-x1530 0.43…0.53 A MPL-x210, MPL-x220, MPL-x230 0.46…0.56 A MPL/MPF-x310, MPL/MPF-x320, MPL/MPF-x330 MPM-x115 0.45…0.55 A MPS-x330 MPL-x420, MPL-x430, MPL-x4520, MPL-x4530, MPL-x4540, MPL-B4560 MPM-x130 0.576…0.704 A MPF-x430, MPF-x4530, MPF-x4540 MPS-x4540 TLY-A110T, TLY-A120T, and TLY-A130T 0.18…0.22 A TLY-A220T and TLY-A230T 0.333…0.407 A TLY-A2530P, TLY-A2540P, and TLY-A310M 0.351…0.429 A (1) Use of the variable x indicates this specification applies to 230V and 460V motors. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 149 150 L3 L1, L2, and L3 inputs apply to 2097-V33PRx-LM and 2097-V34PRx-LM servo drives. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 B+ BR Chassis Shunt Transistor 2097-Rx (1) Shunt B- (1) The 2097-Rx shunt module is external to the Kinetix 350 drive. DC- DC+ Brake Connector Inverter Section V W System Block Diagrams L2 L1 L1 and L2 inputs apply to 2097-V32PRx-LM servo drives. U Three-phase Motor Output Appendix B Interconnect Diagrams This power block diagram applies to 2097-V32PRx-LM, 2097-V33PRx-LM, and 2097-V34PRx-LM, servo drives. Figure 61 - Power Block Diagram Interconnect Diagrams Appendix B This power block diagram applies to 2097-V31PRx-LM, servo drives. The voltage-doubler circuitry lets the drives with 120V input power get full performance from 240V motors. Inverter Section V DCL1 and N inputs apply to 2097-V31PRx-LM servo drives using the voltage-doubler feature. N L2/N L1 (1) The 2097-Rx shunt module is external to the Kinetix 350 drive. Chassis Shunt Transistor 2097-Rx (1) Shunt BR DC+ B+ Brake Connector B- U Three-phase Motor Output W Figure 62 - Voltage Doubler Block Diagram Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 151 Appendix B Interconnect Diagrams Notes: 152 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Appendix C Upgrade the Kinetix 350 Drive Firmware Introduction This appendix provides procedures for upgrading firmware by using ControlFLASH™software. Topic Page Introduction 153 Upgrade Drive Firmware with ControlFLASH Software 154 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 153 Appendix C Upgrade the Kinetix 350 Drive Firmware Upgrade Drive Firmware with ControlFLASH Software Upgrading axis module firmware by using ControlFLASH software involves configuring your Logix communication, selecting the drive to upgrade, and upgrading the firmware. Before You Begin You need the following software and information before you begin. Table 67 - Kinetix 350 System Requirements Description Cat. No. Firmware Revision RSLogix 5000software 9324-RLD300NE 20.x or later RSLinx® software 2.58 or later ControlFLASH firmware upgrade kit(1) 8.00.017 or later Catalog numbers of the targeted Kinetix 350 drive you want to upgrade. Network path to the targeted Kinetix 350 drive module you want to upgrade. (1) Download the ControlFLASH kit from http://support.rockwellautomation.com/controlflash. Contact Rockwell Automation Technical Support at (440) 646-5800 for assistance. For more ControlFLASH information (not drive specific), refer to the ControlFLASH Firmware Upgrade Kit Quick Start, publication 1756-QS105. IMPORTANT Input power or back-up power must be present at IPD or BP connector prior to upgrading your target drive. ATTENTION: To avoid personal injury or damage to equipment during the firmware upgrade due to unpredictable motor activity, do not apply threephase AC. 154 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Upgrade the Kinetix 350 Drive Firmware Appendix C Configure Logix Communication This procedure assumes that your communication method to the Logix controller is using the Ethernet protocol. It is also assumed that your Logix Ethernet module has already been configured. For more information, refer to the ControlLogix System User Manual, publication 1756-UM001. Follow these steps to configure Logix communication. 1. Open your RSLinx Classic software. 2. From the Communications pull-down menu, choose Configure Drivers. The Configure Drivers dialog box opens. 3. From the Available Drive Types pull-down menu, choose Ethernet devices. 4. Click Add New. The Add New RSLinx Classic Driver dialog box opens. 5. Type the new driver name. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 155 Appendix C Upgrade the Kinetix 350 Drive Firmware 6. Click OK. The Configure driver dialog box opens. 7. Type the IP address of your drive. 8. Click OK. The new Ethernet driver appears under Configured Drivers. 9. Click Close. 10. Minimize the RSLinx application dialog box. 156 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Upgrade the Kinetix 350 Drive Firmware Appendix C Upgrade Firmware Follow these steps to select the drive module to upgrade. 1. Open your ControlFLASH software. You can access the ControlFLASH software by either of these methods: • In RSLogix 5000 software from the Tools menu, choose ControlFLASH. • Choose Start>Programs>FLASH Programming Tools> ControlFLASH. The Welcome to ControlFLASH dialog box opens. 2. Click Next. The Catalog Number dialog box opens. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 157 Appendix C Upgrade the Kinetix 350 Drive Firmware 3. Select your drive module and click Next. The Select Device to Update dialog box opens. 4. Expand your Ethernet node, Logix backplane, and EtherNet/IP network module. 5. Select the servo drive to upgrade and click OK. The Firmware Revision dialog box opens. 6. Select the firmware revision to upgrade and click Next. The Summary dialog box opens. 158 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Upgrade the Kinetix 350 Drive Firmware Appendix C 7. Confirm the drive catalog number and firmware revision and click Finish This ControlFLASH warning dialog box opens. 8. Click Yes (only if you are ready). The Progress dialog box opens and upgrading begins. The drive four-digit status indicator changes to -PS- and scrolls IP address, which indicates that upgrading is in progress. After the upgrade information is sent to the drive, the drive resets and performs diagnostic check in. It will display 350, -08-, and scroll -00- and the IP address. 9. Wait for the Progress dialog box to time out. It is normal for this process to take several minutes. IMPORTANT Do not cycle power to the drive during this process or the firmware upgrade will not complete successfully. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 159 Appendix C Upgrade the Kinetix 350 Drive Firmware 10. The Update Status dialog box opens and indicates success or failure as described below. Upgrading Status If Success 1. Update complete appears in a GREEN Status dialog box. 2. Go to step 11. Failure 1. Update failure appears in a RED Status dialog box. 2. Refer to ControlFLASH Firmware Upgrade Kit Quick Start, publication 1756-QS105, for troubleshooting information. 11. Click OK. 160 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Upgrade the Kinetix 350 Drive Firmware Appendix C Verify the Firmware Upgrade Follow these steps to verify your firmware upgrade was successful. TIP Verifying the firmware upgrade is optional. 1. Open your RSLinx software. 2. From the Communications pull-down menu, choose RSWho. 3. Expand your Ethernet node, Logix backplane, and EtherNet/IP network module. 4. Right-click the drive module and choose Device Properties. The Device Properties dialog box opens. 5. Verify the new firmware revision level. 6. Click Close. Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 161 Appendix C Upgrade the Kinetix 350 Drive Firmware Notes: 162 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Index Numerics 120/240V single-phase input power 142 120V single-phase input power 141 240/480V three-phase input power 143 A about this publication 7 AC input power pinouts 34 AC line filters specifications 135 actions tab 90 actuators interconnect diagram MPAI 147 MPAR 147 MPAS 146 TLAR 148 additional resources 8 apply power 91 axis module axis properties 88 status indicators 117 axis unstable 119 B back-up power 39 pinouts 34 block diagrams power block diagram 150 voltage-doubler block diagram 151 bond 21 EMI (electromagnetic interference) 20 high frequency energy 22 subpanels 22 brake currents 149 brake/DC bus connector 71 build your own cables 48 C cables build your own cables 48 Ethernet cable length 72 length, CE 16 maximum fdbk cable length 133 motor feedback 67 motor power 62 shield clamp 66 catalog numbers 12 category 3 requirements 100 stop category definitions 100 CE compliance 13, 53 comply with CE 104 conformity 104 invalidate compliance 53 meet requirements 104 certification specifications 134 TÜV Rheinland 100 user responsibilities 100 circuit breaker selection 17 specifications 131 clamp 66 clean zone 23 clearance requirements 19 configure axis properties 88 delay times 90 drive modules 85 EtherNet/IP controller 82 connect Ethernet 72 external shunt resistor 71 feedback 67 I/O 67 motor shield clamp 66 connector designators 30 locations 30, 103 contactor specifications 132 ControlFLASH firmware upgrade 153 troubleshooting 160 verify upgrade 161 controller properties 82 conventions used in this manual 7 D data type 86 date/time tab 83 delay times 90 digital inputs 35 dimensions 137 dirty zone 23 download program 91 drive wire BP connector 59 wire IPD connector 60 wire MP connector 61 wire STO connector 59 wiring requirements 56 drive status indicator 118 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 163 Index E EMC directive 104 motor ground termination 61 motor ground termination at motor 61 EMI (electromagnetic interference) bonding 20 EN 61508 101 EN 62061 101 enable time synchronization 83 enableInputChecking 93, 98 enclosure requirements 16 sizing 18 environmental specifications 133 erratic operation 120 Ethernet cable length 72 cables RJ45 connector 72 pinouts 33 wiring 72 F fault code summary 111 fault codes 111 fault status only 121 feedback connections 67 feedback power supply 45 firmware upgrade 153 verify upgrade 161 fuse selection 17 specifications 131 G generic TTL incremental 40 ground multiple subpanels 55 system to subpanel 54 grounded power configuration 49 back-up power 39 pinouts 32 input power wiring 3-phase Delta 49 3-phase WYE 49 determine input power 48 grounded power configuration 49 single-phase 50 voltage doubler 50 single-phase amplifiers on 3-phase power 51, 52 install drive accessories I/O terminal block 69 low-profile connector kits 70 shunt resistor 71 install your drive bond subpanels 22 circuit breakers 17 fuse selection 17 HF bonding 20 system mounting requirements 16 transformer 17 integrated axis module axis properties 88 status indicators 117 interconnect diagrams 120/240V single-phase input power 142 120V single-phase input power 141 2097 with MPAI actuator 147 2097 with MPAR actuator 147 2097 with MPAS actuator 146 2097 with MPL/MPM/MPF/MPS motor 144 2097 with TLAR actuator 148 2097 with TLY motor 145 240/480V three-phase input power 143 notes 140 shunt resistor 143 interpreting status indicators 110 ISO 13849-1 CAT 3 requirements 100 stop category definitions 100 L low profile connector kits wiring 70 low voltage directive 104 H hardware enable input 93, 96 HF bonding 20 high frequency energy 22 hookup test 93 I I/O specifications 35 I/O connections 67 I/O connector wiring 69 I/O specifications 164 M maximum fdbk cable length 133 specifications 133 module properties drive modules 85 motion group properties 87 motor feedback pinouts 33 specifications general 40 thermostat 41 wiring 67 motor power pinouts 34 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Index wiring 62 motor tab 88 motors accel/decel problems 119 brake currents 149 feedback pinouts 68 ground termination 61 interconnect diagram MPL/MPM/MPF/MPS 144 TLY 145 overheating 120 power wiring 3-phase and brake 64 3-phase only 63 TL-Series 62 shield clamp wiring 66 test 92 tune 92 velocity 119 mount Kinetix 350 drive 28 MSG instruction 98 N network status indicator 118 noise 23 abnormal 120 feedback 119 P panel requirements 16 parameters 90 PFD and PFH data 102 PFD and PFH definition 102 pinouts AC input power (IPD) 34 back-up power (BP) 34 Ethernet (Port 1) 33 I/O (IOD) 32 motor feedback (MF) 33 motor feedback connector 68 motor power (MP) 34 safe torque-off (STO) 31 shunt resistor and DC bus (BC) 34 PORT 1 status indicator 118 power block diagram 150 power dissipation specifications 133 power specifications single and three phase 129 single phase 128 three phase 130 power supply, feedback 45 powerup 91 proof tests 101 publications, related 8 R related publications 8 requirements clearance 19 RJ45 Ethernet connector 72 route power and signal wiring 48 RSLogix 5000 software 82 S safe torque-off bypass 106 connector location 103 operation 101, 106 PFD and PFH data 102 PFD and PFH definition 102 pinouts 31 proof tests 101 specifications 108 troubleshooting 102 wiring diagram 107 wiring requirements 105 safety products catalog 107 shield clamp 66 shunt resistor 26 interconnect diagram 143 specifications 136 wiring requirements 57 shunt resistor and DC bus pinouts 34 shutdown 121 software RSLogix 5000 82 specifications AC line filters 135 back-up power 39 certifications 134 circut breaker 131 contactor ratings 132 digital inputs 35 drive power single and three-phase 129 single-phase 128 three-phase 130 environmental 133 feedback power supply 45 fuse 131 maximum fdbk cable length 133 motor feedback 40 generic TTL 43 Stegmann 42 Tamagawa 44 motor thermostat interface 41 power dissipation 133 product dimensions 137 safe torque-off 108 shunt reisitor 136 transformer 132 weight 134 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 165 Index status indicators 110, 117 drive status 118 PORT 1 status 118 Stegmann 40 stop drive 121 stop planner 121 system block diagrams power block diagram 150 voltage-doubler block diagram 151 system mounting requirements 16 system overview 10 diagram 11 T Tamagawa 40 test axes hookup test 93 training 7 transformer sizing 17 specifications 132 troubleshooting 118 ControlFLASH 160 drive status indicator 118 exception behavior 121 fault code summary 111 fault codes 111 fault status only 121 four-digit display messages 110 general system problems 119 abnormal noise 120 axis unstable 119 erratic operation 120 feedback noise 119 motor accel/decel 119 motor overheating 120 motor velocity 119 no rotation 120 Logix/drive fault behavior 121 network status indicator 118 PORT 1 status indicator 118 safe torque-off 102 safety precautions 109 shutdown 121 stop drive 121 stop planner 121 tune axes autotune tab 95 V voltage doubler block diagram 151 operation 50 power diagram 141 W weight specifications 134 who should use this manual 7 wiring 166 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 build your own cables 48 diagram, safe torque-off 107 drive BP connector 59 IPD connector 60 MP connector 61 STO connector 59 Ethernet connections 72 grounded power configuration 49 grounding drive 54 guidelines 58 I/O connector 69 input power determine type 48 low profile connectors 70 motor cable shield clamp 66 motor feedback 67 motor power 62, 63, 64 requirements 47, 105 drive 56 shunt resistor 57 route power and signal wiring 48 shunt resistor 71 Index Notes: Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 167 Index 168 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Rockwell Automation Support Rockwell Automation provides technical information on the Web to assist you in using its products. 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If you have any suggestions on how to improve this document, complete this form, publication RA-DU002, available at http://www.rockwellautomation.com/literature/. Rockwell Otomasyon Ticaret A.Ş., Kar Plaza İş Merkezi E Blok Kat:6 34752 İçerenköy, İstanbul, Tel: +90 (216) 5698400 www.rockwel lautomation.com Power, Control and Information Solutions Headquarters Americas: Rockwell Automation, 1201 South Second Street, Milwaukee, WI 53204-2496 USA, Tel: (1) 414.382.2000, Fax: (1) 414.382.4444 Europe/Middle East/Africa: Rockwell Automation NV, Pegasus Park, De Kleetlaan 12a, 1831 Diegem, Belgium, Tel: (32) 2 663 0600, Fax: (32) 2 663 0640 Asia Pacific: Rockwell Automation, Level 14, Core F, Cyberport 3, 100 Cyberport Road, Hong Kong, Tel: (852) 2887 4788, Fax: (852) 2508 1846 Rockwell Automation Publication 2097-UM002A-EN-P - August 2011 Copyright © 2011 Rockwell Automation, Inc. All rights reserved. Printed in the U.S.A. Kinetix 350 Single-axis EtherNet/IP Servo Drives User Manual